Mechanical latch module

What is claimed is: 1. A latch module, for connecting to a retaining pin of a chassis, comprising: a button carriage comprising a user-operable button, wherein the button carriage is slidably coupled to a latch module chassis of the latch module, thereby enabling the button carriage to move between an extended and a depressed position with respect to the latch module chassis, and wherein the button carriage, when the button is depressed a first time, moves from the extended position to the depressed position; an inverter arm, wherein the inverter arm is pivotally coupled to the latch module chassis, wherein the inverter arm is mechanically linked to the button carriage at a first end of the inverter arm, and wherein the button carriage, moving from the extended position to the depressed position, as the button is depressed, causes the inverter arm to pivot; a latch arm, mechanically linked to a second end of the inverter arm, wherein the latch arm is slidably coupled to the latch module chassis, wherein pivoting of the inverter arm causes the latch arm to slide from a non-blocking position into a blocking position, wherein, in the blocking position, the latch arm extends toward and makes contact with the retaining pin of the chassis, and wherein, in the non-blocking position, the latch arm is away from and not in contact with the retaining pin of the chassis; and a latch biasing spring between the button carriage and the inverter arm, generating a biasing force that, in the blocking position, causes the inverter arm to exert a force against the retaining pin. 2. The latch module of claim 1 , further comprising: a button carriage biasing spring, wherein the button carriage biasing spring generates a force opposing the sliding movement of the button carriage as the button carriage moves from the extended position to the depressed position. 3. The latch module of claim 2 , further comprising: a locking mechanism that fixes the button carriage in the depressed position when the button is depressed for the first time, wherein the locking mechanism is configured to lock the button carriage in the depressed position after the button is released after the first time it is depressed. 4. The latch module of claim 3 , wherein the locking mechanism is further configured to release the button carriage from the depressed position when the button is depressed and released a second time. 5. The latch module of claim 3 , wherein the locking mechanism comprises: a self-centering follower arm, wherein the follower arm is pivotally linked to the button carriage, and wherein the follower arm is configured to move in an engaging segment of a follower arm track circuit from a disengaged position where the follower arm is in a centered state to an engaged position, when the button is depressed for the first time, wherein the follower arm is in the disengaged position when the button carriage is in the extended position; wherein the follower arm is in the engaged position when the button carriage is in the depressed position; and wherein the engaging segment of the follower arm track circuit is shaped to: drive the follower arm away from the centered state as the button carriage moves from the extended to the depressed position; and hold the follower arm and the mechanically linked button carriage in the depressed position as the user releases the button. 6. The latch module of claim 5 , wherein the follower arm is further configured to move in a disengaging segment of the follower arm track circuit, different from the engaging segment, from the engaged position to the disengaged position when the button is pressed and released the second time, wherein the disengaging segment is shaped to: enable the follower arm to return to the centered state as the user releases the button and the button carriage returns to the extended position. 7. The latch module of claim 5 , wherein the locking mechanism further comprises an extension spring for returning the self-centering follower arm to the centered state. 8. The latch module of claim 5 , wherein the follower arm track circuit is a grove in the latch module chassis. 9. The latch module of claim 1 , wherein the inverter arm increases the biasing force. 10. The latch module of claim 1 , wherein the latch biasing spring is a compression spring. 11. The latch module of claim 1 , wherein the latch biasing spring is housed in a cavity of the button carriage, wherein a plunger caps the cavity and interfaces with the inverter arm; and wherein the plunger is configured to slidably move into the cavity as the latch arm reaches the blocking position, thereby compressing the latch biasing spring. 12. A latch module, for connecting to a retaining pin of a chassis, comprising: a button carriage comprising a user-operable button, wherein the button carriage is slidably coupled to a latch module chassis of the latch module, thereby enabling the button carriage to move between an extended and a depressed position with respect to the latch module chassis, and wherein the button carriage, when the button is depressed a first time, moves from the extended position to the depressed position; an inverter arm, wherein the inverter arm is pivotally coupled to the latch module chassis, wherein the inverter arm is mechanically linked to the button carriage at a first end of the inverter arm, and wherein the button carriage, moving from the extended position to the depressed position, as the button is depressed, causes the inverter arm to pivot; a latch arm, mechanically linked to a second end of the inverter arm, wherein the latch arm is slidably coupled to the latch module chassis, wherein pivoting of the inverter arm causes the latch arm to slide from a non-blocking position into a blocking position, wherein, in the blocking position, the latch arm extends toward and makes contact with the retaining pin of the chassis, and wherein, in the non-blocking position, the latch arm is away from and not in contact with the retaining pin of the chassis; and a lock arm, pivotally coupled to the latch module chassis, wherein the lock arm is configured to engage with the button carriage, thereby preventing the button carriage from leaving the extended position, when the lock arm is not actuated by the retaining pin. 13. The latch module of claim 12 , wherein the lock arm is further configured to disengage from the button carriage, thereby enabling the button carriage to move to leave the extended position, when the lock arm is actuated by the retaining pin. 14. A latch module, for connecting to a retaining pin of a chassis, comprising: a button carriage comprising a user-operable button, wherein the button carriage is slidably coupled to a latch module chassis of the latch module, thereby enabling the button carriage to move between an extended and a depressed position with respect to the latch module chassis, and wherein the button carriage, when the button is depressed a first time, moves from the extended position to the depressed position; an inverter arm, wherein the inverter arm is pivotally coupled to the latch module chassis, wherein the inverter arm is mechanically linked to the button carriage at a first end of the inverter arm, and wherein the button carriage, moving from the extended position to the depressed position, as the button is depressed, causes the inverter arm to pivot; a latch arm, mechanically linked to a second end of the inverter arm, wherein the latch arm is slidably coupled to the latch module chassis, wherein pivoting of the inverter arm