Sliding door seal

What is claimed is: 1 . A seal mechanism for a sliding door, the seal mechanism comprising: a channel member configured for mounting to the sliding door; a seal member movably mounted in the channel member for movement between a withdrawn position and a deployed position; an actuation lever pivotably mounted in the channel member for pivotal movement about a pivot axis between an unactuated position and an actuated position, wherein the actuation lever comprises: an input arm positioned below the pivot axis, the input arm including a first portion that extends downward from the pivot axis and a foot that is positioned below the first portion and extends in a direction of the pivot axis; and an output arm positioned above the pivot axis; and a transmission configured to move the seal member between the withdrawn position and the deployed position in response to movement of the actuation lever between the unactuated position and the actuated position. 2 . The seal mechanism of claim 1 , wherein the actuation lever is configured to translate an input force on the actuation lever to an output force on the transmission; and wherein the actuation lever is configured to provide a mechanical force advantage such that the output force is greater than the input force. 3 . The seal mechanism of claim 1 , wherein the transmission comprises a leaf spring. 4 . The seal mechanism of claim 3 , wherein the leaf spring comprises a curved portion; wherein the curved portion is configured to drive the seal member toward the deployed position in response to a reduction in an effective longitudinal length of the leaf spring; and wherein the curved portion is configured to drive the seal member toward the withdrawn position in response to an increase in the effective longitudinal length of the leaf spring. 5 . The seal mechanism of claim 4 , wherein the curved portion comprises a valley that is received in a channel of the seal member; and wherein the seal member comprises a pin received in the valley. 6 . The seal mechanism of claim 1 , wherein the channel member extends in a longitudinal direction; wherein the withdrawn position and the deployed position are offset from one another in a lateral direction transverse to the longitudinal direction; and wherein the transmission is configured to translate a longitudinal force exerted by the actuation lever to a lateral force on the seal member. 7 . The seal mechanism of claim 1 , wherein the actuation lever further comprises a jog that partially defines a void, the jog connected between the first portion and the foot; and wherein a portion of the seal member extends through the void. 8 . The seal mechanism of claim 1 , wherein the transmission comprises: a rod pivotably coupled to the output arm; and a leaf spring engaged between the rod and the seal member; and wherein the leaf spring causes the rod to urge the actuation lever toward the unactuated position. 9 . The seal mechanism of claim 1 , wherein the foot is located at a lower mouth of the channel member. 10 . A sliding door system, comprising: a frame; a sliding door mounted in the frame for sliding movement between an open position and a closed position; and a drop seal mechanism mounted within the sliding door, the drop seal mechanism having a deployed state in which the drop seal mechanism forms a seal with the frame, the drop seal mechanism having a retracted state in which the drop seal mechanism does not form a seal with the frame; wherein the frame comprises a projection configured to drive the drop seal mechanism from the retracted state to the deployed state as the sliding door slides from the open position to the closed position; and wherein the drop seal mechanism comprises: an actuation lever pivotably mounted in the sliding door for movement between an unactuated position and an actuated position; and a rod pivotably connected with the actuation lever. 11 . The sliding door system of claim 10 , wherein the drop seal mechanism is concealed within the sliding door when in the retracted state. 12 . The sliding door system of claim 10 , wherein the actuation lever is wholly concealed within the sliding door. 13 . The sliding door system of claim 10 , wherein the actuation lever is configured to provide a mechanical force advantage such that a lesser input force exerted by the projection on the actuation lever results in a greater output force exerted by the actuation lever on the rod. 14 . The sliding door system of claim 10 , wherein the drop seal mechanism further comprises: a seal member mounted for movement between a withdrawn position and a deployed position; and a transmission configured to move the seal member between the withdrawn position and the deployed position in response to movement of the actuation lever between the unactuated position and the actuated position; and wherein the transmission comprises the rod. 15 . The sliding door system of claim 14 , wherein the transmission further comprises a leaf spring extending in a longitudinal direction; wherein the leaf spring comprises a curved portion extending at least partially in a lateral direction transverse to the longitudinal direction; and wherein contraction of the leaf spring in the longitudinal direction causes expansion of the leaf spring in the lateral direction to thereby urge the seal member from the withdrawn position to the deployed position. 16 . The sliding door system of claim 10 , wherein the sliding door is configured to move in a first direction from the open position to the closed position; and wherein the projection is configured to drive the drop seal mechanism from the retracted state to the deployed state by exerting on the drop seal mechanism an input force at least primarily in a second direction opposite the first direction. 17 . A method of forming a seal between a sliding door and a frame, the method comprising: during sliding movement of the sliding door in a first direction from an open position to a closed position, causing a portion of the frame to exert a first force on an actuation lever pivotably mounted within the sliding door, wherein the first force is exerted at least primarily in a second direction opposite the first direction; and in response to the first force on the actuation lever, causing the actuation lever to exert a second force on a transmission, thereby causing the transmission to drive a seal member from a withdrawn position, in which the seal member does not form the seal between the sliding door and the frame, to a deployed position, in which the seal member forms the seal between the sliding door and the frame. 18 . The method of claim 17 , further comprising providing a mechanical force advantage with the actuation lever such that the second force is greater than the first force. 19 . The method of claim 17 , wherein the transmission comprises a leaf spring including a curved portion; and wherein causing the transmission to drive the seal member from the withdrawn position to the deployed position comprises reducing an effective longitudinal length of the leaf spring to thereby cause the curved portion to urge the seal member toward the deployed position. 20 . The method of claim 17 , wherein the actuation lever comprises a void; and wherein a portion of the seal member travels within the void as the seal member moves between the withdrawn position and the deployed position.