A spring damper device comprising a directional spring (e.g., coil) having first and second ends, and defining an inner diameter region. A damper (e.g., viscoelastic polymer slug) comprising an element of elasticity configured to be situated within the inner diameter region of the directional spring. In response to a load on the spring damper device, the directional spring operates to compress, and the damper operates to dampen vibration associated with the load. The damper can comprise a viscoelastic damper comprising both an element of viscosity and the element of elasticity. The damper can be substantially coaxially aligned with the directional spring. Spring damper device(s) can be preloaded in a micro adjustment mechanism to account for positional adjustments between two structures (e.g., between a scope and a firearm), such that the spring(s) attenuate a shock impulse event (e.g., when firing), while the damper(s) attenuate vibration (e.g., to prevent damage the scope).

An optical sight, system, and method for a firearm. The optical sight includes a housing including a base. A first support and a second support extend from the base. A top support extends between the first support and the second support. The top support extends over an optical element and includes a surface adjacent to the optical element. A second cross member defining one or more openings between the first cross member and the first and second supports. An optical element supported by said housing between said first support and said second support. A reticle is displayed on the optical element.

An optical sight and system. The optical sight includes a housing including a base. A first support and a and a second support extend from the base. A top support extends between the first support and the second support. The top support extends over an optical element and includes a surface adjacent to the optical element. The top support of the housing defines at least one opening extending above a portion of the optical element. The optical element is supported by the housing between the base, the first support, and the second support.

A method for forming a weapon accessory mounting device to attach to a projectile firing weapon is disclosed. A flexure for receiving a body of the weapon accessory is formed. A pivot portion is formed at a first end of the flexure to attach the flexure to the weapon at a first attachment region. A second attachment portion is formed at a second end of the flexure to attach the flexure to the weapon at a second attachment region. A first aperture is formed in the pivot portion configured to receive a pivot pin. A second aperture in the weapon accessory body receives the pivot pin at a weapon accessory body first end to attach the weapon accessory body first end to the pivot portion. The pivot portion is configured to convert at least a portion of energy of a weapon shock recoil from translational energy to rotational energy.

Implementations of an adapter plate system for mounting optical sights on a pistol are provided. An example adapter plate system for mounting optical sights on a pistol comprises: a pistol slide, the pistol slide includes an adapter interface, the adapter interface comprising a bottom surface that extends between a first end wall and a second end wall; and an adapter plate, the adapter plate includes a mounting surface on a top side thereof, the mounting surface is configured so that an optical sight can be attached thereto. The adapter plate is configured so that it can be rotated into position between the first end wall and the second end wall of the adapter interface.

A system includes a mounting portion with a planar elongated geometry and an accessory portion having a geometry similar to the mounting portion. The mounting portion includes an alignment recess formed centrally on one side of the mounting portion to extend partially into a thickness of the mounting portion, a mount-side magnet seat formed in the one side of the mounting portion, and a mount-side magnet disposed in the mount-side magnet seat. The accessory portion includes an alignment projection formed centrally on one side of the accessory portion to extend outward from the accessory portion to engage with the alignment recess to align the accessory portion with the mounting portion, an accessory-side magnet seat formed in the one side of the mounting portion, and an accessory-side magnet disposed in the magnet seat to engage with the mount-side magnet to removably secure the accessory portion relative to the mounting portion.

Implementations of an optical sight mounting system are provided. An example optical sight mounting system comprises an optical sight having a base that can be secured to a pistol slide having an adapter interface. The base of the optical sight is configured so that it can be rotated into position within the adapter interface. In this way, the optical sight can be mounted on a pistol and used to aim. Another example optical sight mounting system comprises an optical sight having a base that can be secured to an adapter interface of an optical sight mount. The base of the optical sight is configured so that it can be rotated into position within the adapter interface. The optical sight mount is configured to releasable engage a mounting interface of a firearm (e.g., a MIL-STD-1913 rail). In this way, the optical sight can be positioned on a firearm (e.g., a rifle) and used to aim.

A shock attenuation system configured to reduce shock experienced by an optical device coupled to a weapon includes an inner rail support configured to couple to the weapon and at least two outer rail supports substantially parallel to the inner rail support. The at least two outer rail supports are configured to couple to the optical device. The shock attenuation system also includes a first spring feature coupled to a first of the at least two outer rail supports and the inner rail support, and a second spring feature coupled to a second of the at least two outer rail supports and the inner rail support. The shock attenuation system further includes a viscoelastic material coupled to at least one of: the inner rail support, the first outer rail support, the second outer rail support, the first spring feature, or the second spring feature.

Disclosed is a passive shock-absorbing system for a sighting apparatus installed on a device including equipment generating the shocks, the system including two rigid plates substantially parallel to one another, via a first plate secured to the part of the device including the equipment and a second plate secured to the sighting apparatus, the plates being connected to one another by a position return component returning the plates to a determined relative rest position after absorbing a shock. The system is characterized in that the position return component includes a line-point-plane positioning unit with balls between the two plates and a set of elastic return members connecting the two plates to one another. A corresponding device is also desclosed.

Devices mountable to a rail having a recoil groove are provided. In one aspect a device mountable to a rail having a recoil groove has a rail positioner having a longitudinal length with a plurality of teeth arranged along an edge of the longitudinal length and a recoil groove insert extending away from the rail positioner and configured to be inserted into the recoil groove, a first body member having a first rail engagement surface and plurality of openings generally sized to receive the plurality of teeth and arranged along a length of the first body a second body member having a second rail engagement surface opposite the first body member, and a clamping structure operable to tighten and maintain a clamping force between the first body member and the second body member when the rail positioner is arranged in therein and that can be released facilitate installation and removal of the mounting to a rail.