Damping valve and shock absorber

The invention claimed is: 1. A damping valve comprising: a valve seat member having a port, an annular window communicated with an outlet end of the port, an inner circumference valve seat provided on an inner circumferential side of the annular window, and an outer circumference valve seat of the annular window; a first valve element formed to have an annular shape and stacked on the valve seat member, the first valve element being configured to open and close the annular window by being seated on and separated from the outer circumference valve seat, and the first valve element having a hole facing the annular window and forming a throttle or a passage in communication with a throttle; a second valve element formed to have an annular shape and provided between the inner circumference valve seat of the valve seat member and the first valve element, the second valve element being configured to open and close the hole; and a biasing member configured to bias the first valve element towards the second valve element, wherein a surface of the second valve element on an opposite side from the valve seat member is higher than the outer circumference valve seat of the valve seat member when viewed from a direction orthogonal to an axial direction of the valve seat member, and the first valve element is configured to be seated on the outer circumference valve seat by being subjected to a biasing force of the biasing member. 2. The damping valve according to claim 1 , wherein the biasing member has: an annular plate having elasticity and arranged on the opposite side of the first valve element from the valve seat member; and a ring formed to have an annular shape and provided between the first valve element and the annular plate, the ring having an inner diameter larger than inner diameters of the first valve element and the annular plate, but smaller than outer diameters of the first valve element and the annular plate. 3. The damping valve according to claim 1 , wherein the biasing member comprises an elastic body configured to bias the first valve element from the opposite side from the valve seat member. 4. The damping valve according to claim 1 , further comprising a throttle valve element formed to have an annular shape and stacked on the opposite side of the first valve element from the valve seat member, and the throttle valve element having the throttle in communication with the hole. 5. The damping valve according to claim 1 , further comprising a fixed orifice provided in an outer circumference of the first valve element or in the outer circumference valve seat of the valve seat member. 6. A shock absorber comprising: a cylinder; a piston inserted into the cylinder in a freely movable manner, the piston being configured to partition an interior of the cylinder into an extension-side chamber and a compression-side chamber; a piston rod inserted into the cylinder and linked to the piston; an outer tube arranged on an outer circumferential side of the cylinder so as to form a reservoir chamber in an interior of the outer tube; a valve case provided in an end portion of the cylinder, the valve case being configured to divide the compression-side chamber and the reservoir chamber; a piston-side valve provided on a side of the extension-side chamber in the piston, the piston-side valve being configured to open and close a compression-side port provided in the piston; a case-side valve provided on a side of the compression-side chamber in the valve case, the case-side valve being configured to open and close a suction port provided in the valve case; and a damping valve according to claim 1 , wherein the valve seat member is the piston, and the first valve element is arranged on a side of the compression-side chamber in the piston. 7. The shock absorber according to claim 6 , further comprising: a damping passage configured to allow the extension-side chamber to communicate with the reservoir chamber; and a variable damping valve provided in the damping passage, the variable damping valve being configured to impart resistance to a flow of fluid flowing from the extension-side chamber towards the reservoir chamber. 8. A shock absorber comprising: a cylinder; a piston inserted into the cylinder in a freely movable manner, the piston being configured to partition an interior of the cylinder into an extension-side chamber and a compression-side chamber; a piston rod inserted into the cylinder and linked to the piston; an outer tube arranged on an outer circumferential side of the cylinder so as to form a reservoir chamber in an interior of the outer tube; a valve case provided in an end portion of the cylinder, the valve case being configured to divide the compression-side chamber and the reservoir chamber; a piston-side valve provided on a side of the extension-side chamber in the piston, the piston-side valve being configured to open and close a compression-side port provided in the piston; a case-side valve provided on a side of the compression-side chamber in the valve case, the case-side valve being configured to open and close a suction port provided in the valve case; and a damping valve according to claim 1 , wherein the valve seat member is the valve case, and the first valve element is arranged on a side of the reservoir chamber in the valve case. 9. The shock absorber according to claim 8 , further comprising: a damping passage configured to allow the extension-side chamber to communicate with the reservoir chamber; and a variable damping valve provided in the damping passage, the variable damping valve being configured to impart resistance to a flow of fluid flowing from the extension-side chamber towards the reservoir chamber. 10. A shock absorber comprising: a cylinder; a piston inserted into the cylinder in a freely movable manner, the piston being configured to partition an interior of the cylinder into an extension-side chamber and a compression-side chamber; a piston rod inserted into the cylinder and linked to the piston; an outer tube arranged on an outer circumferential side of the cylinder so as to form a reservoir chamber in an interior of the outer tube; a valve case provided in an end portion of the cylinder, the valve case being configured to divide the compression-side chamber and the reservoir chamber; a piston-side valve provided on a side of the extension-side chamber in the piston, the piston-side valve being configured to open and close a compression-side port provided in the piston; a case-side valve provided on a side of the compression-side chamber in the valve case, the case-side valve being configured to open and close a suction port provided in the valve case; and a damping valve according to claim 1 , wherein the valve seat member is the piston, the first valve element is arranged on a side of the compression-side chamber in the piston, the valve seat member is the valve case, the first valve element is arranged on a side of the reservoir chamber in the valve case. 11. The shock absorber according to claim 10 , further comprising: a damping passage configured to allow the extension-side chamber to communicate with the reservoir chamber; and a variable damping valve provided in the damping passage, the variable damping valve being configured to impart resistance to a flow of fluid flowing from the extension-side chamber towards the reservoir chamber. 12. The damping valve according to claim 1 , wherein the biasing member is configured to cause the first valve element to be seated on the outer circumference valve seat by deforming the second valve element together with the first va