Load sensor and electromechanical brake system

The invention claimed is: 1. A load sensor comprising: a flange member configured to deflect when receiving, at a load receiving portion, a load from a front side in an axial direction; a support member configured to support the flange member from a rear side in the axial direction, at a support portion displaced from the load receiving portion in a radial direction orthogonal to the axial direction; a displacement detecting mechanism configured to detect a movement amount of the flange member relative to the support member; and a variable detection sensitivity mechanism configured to enable the relative movement amount with respect to a change of the load applied to the flange member to be larger in a low load range in which the load is equal to or lower than a predetermined load value than in a high load range in which the load is higher than the predetermined load value, wherein the variable detection sensitivity mechanism comprises an elastic member disposed between the flange member and the support member, the elastic member being configured such that, while the load is equal to or lower than the predetermined load value, the elastic member is expandable and compressible according to a magnitude of the load so as to allow the flange member and the support member to move relative to each other in directions in which the elastic member is expanded and compressed. 2. A load sensor comprising: a flange member configured to deflect when receiving, at a load receiving portion, a load from a front side in an axial direction; a support member configured to support the flange member from a rear side in the axial direction, at a support portion displaced from the load receiving portion in a radial direction orthogonal to the axial direction; a displacement detecting mechanism configured to detect a movement amount of the flange member relative to the support member; and a variable detection sensitivity mechanism configured to enable the relative movement amount with respect to a change of the load applied to the flange member to be larger in a low load range in which the load is equal to or lower than a predetermined load value than in a high load range in which the load is higher than the predetermined load value, wherein the support portion comprises: a first support portion at which the flange member and the support member abut against each other while the load is equal to or lower than the predetermined load value; and a second support portion at which the flange member and the support member abut against each other while the load is higher than the predetermined load value, and wherein the variable detection sensitivity mechanism includes the first support portion and the second support portion. 3. The load sensor according to claim 1 , wherein the displacement detecting mechanism comprises: a magnetic target on a first one of the flange member and the support member, the magnetic target being configured to generate a magnetic flux; and a magnetic sensor element on a second one of the flange member and the support member, the magnetic sensor element being configured to detect the magnetic flux generated by the magnetic target. 4. The load sensor according to claim 2 , wherein the displacement detecting mechanism comprises: a magnetic target on a first one of the flange member and the support member, the magnetic target being configured to generate a magnetic flux; and a magnetic sensor element on a second one of the flange member and the support member, the magnetic sensor element being configured to detect the magnetic flux generated by the magnetic target. 5. An electromechanical brake system comprising: an electric motor; a rotary shaft configured to be rotated about an axis of the rotary shaft by a rotational driving force of the electric motor; a linear motion member movable in an axial direction of the rotary shaft; a linear motion conversion mechanism configured to convert rotation of the rotary shaft into an axial movement of the linear motion member; a friction pad disposed on a first side of the linear motion member with respect to the axial direction, the friction pad being configured to move in the axial direction with the axial movement of the linear motion member; and the load sensor according to claim 1 , the load sensor being configured to detect a load due to a reaction force from the friction pad. 6. An electromechanical brake system comprising: an electric motor; a rotary shaft configured to be rotated about an axis of the rotary shaft by a rotational driving force of the electric motor; a linear motion member movable in an axial direction of the rotary shaft; a linear motion conversion mechanism configured to convert rotation of the rotary shaft into an axial movement of the linear motion member; a friction pad disposed on a first side of the linear motion member with respect to the axial direction, the friction pad being configured to move in the axial direction with the axial movement of the linear motion member; and the load sensor according to claim 2 , the load sensor being configured to detect a load due to a reaction force from the friction pad. 7. An electromechanical brake system comprising: an electric motor; a rotary shaft configured to be rotated about an axis of the rotary shaft by a rotational driving force of the electric motor; a linear motion member movable in an axial direction of the rotary shaft; a linear motion conversion mechanism configured to convert rotation of the rotary shaft into an axial movement of the linear motion member; a friction pad disposed on a first side of the linear motion member with respect to the axial direction, the friction pad being configured to move in the axial direction with the axial movement of the linear motion member; and the load sensor according to claim 3 , the load sensor being configured to detect a load due to a reaction force from the friction pad. 8. An electromechanical brake system comprising: an electric motor; a rotary shaft configured to be rotated about an axis of the rotary shaft by a rotational driving force of the electric motor; a linear motion member movable in an axial direction of the rotary shaft; a linear motion conversion mechanism configured to convert rotation of the rotary shaft into an axial movement of the linear motion member; a friction pad disposed on a first side of the linear motion member with respect to the axial direction, the friction pad being configured to move in the axial direction with the axial movement of the linear motion member; and the load sensor according to claim 4 , the load sensor being configured to detect a load due to a reaction force from the friction pad.