Firearm laser sight alignment assembly

The invention claimed is: 1. A firearm comprising: a barrel having a longitudinal firing axis; a frame forming a substantially hollow chamber beneath the barrel; a laser module disposed within the chamber and moveable relative to the frame, the laser module configured to selectively emit a beam of radiation exiting the frame along a beam path; a first alignment pin moveably connected to the frame and contacting the laser module, wherein movement of the first alignment pin results in movement of the laser module relative to the frame; a resilient coupling having an internal seat engaging the laser module and an external seat forming an adhesive-free interference fit with the frame; and a cover removably connected to the frame, the cover forming an adhesive-free interference fit with the external seat; wherein an engagement between the resilient coupling and at least one of the cover or the frame applies a biasing force to the laser module, and wherein movement of the first alignment pin results in movement of the laser module against or in a same direction as the biasing force. 2. The firearm of claim 1 , wherein movement of the laser module, in response to movement of the first alignment pin, aligns the beam path with the firing axis such that the beam path intersects the firing axis at a point of impact disposed a predetermined distance from the firearm. 3. The firearm of claim 1 , wherein the movement of the laser module relative to the frame comprises angular movement of the laser module. 4. The firearm of claim 3 , further comprising a second alignment pin movably connected to the frame and contacting the laser module, wherein movement of the first alignment pin in a first linear direction substantially transverse to the firing axis causes movement of the laser module in a first angular direction, and wherein movement of the second alignment pin in a second linear direction substantially transverse to the firing axis results in movement of the laser module in a second angular direction. 5. The firearm of claim 1 , further comprising a biasing device applying a biasing force to the laser module, wherein movement of the first alignment pin results in movement of the laser module against or in a same direction as the biasing force. 6. The firearm of claim 1 , further comprising a power supply configured to provide power to the laser module, wherein the power supply is disposed within the frame at least one of beneath or rearward of the laser module. 7. The firearm of claim 6 , further comprising a switch operably connected to the power supply and including an arm accessible from outside of the frame, wherein movement of the arm at least partially through the frame directs power from the power supply to the laser module. 8. A method of moving a laser module disposed within a frame of a firearm, comprising: moving an alignment pin movably connected to an outer wall of the frame to contact the laser module; removably connecting a cover to the frame to substantially enclose the laser module within a chamber formed by the frame; and forming an adhesive-free interference fit between the cover and a resilient coupling engaged with an outer seat of the laser module, wherein movement of the alignment pin results in movement of the laser module relative to the frame and wherein removably connecting the cover to the frame applies a biasing force to the laser. 9. The method of claim 8 , wherein movement of the alignment pin results in angular movement of the laser module, and the angular movement aligns a beam path associated with the laser module with a firing axis of the firearm such that the beam path intersects the firing axis at a point of impact disposed a predetermined distance from the firearm. 10. The method of claim 8 , wherein linear movement of the alignment pin in a first direction substantially transverse to a firing axis of the firearm pivots the laser module relative to the firing axis. 11. The method of claim 10 , wherein pivoting the laser module relative to the firing axis comprises at least one of: movement of the laser module against the direction of a biasing force; or movement of the laser module in a same direction as a biasing force applied to the laser module by a biasing device disposed at least partially within the frame.