Patent Application
20220357131
This application relates generally to rail mounting assemblies and, more particularly, to compact rail mounting assemblies.
Rail mounting assemblies are used to mount devices such as optical sights or other accessories onto rifles, similar weapons, or other devices that generate significant shock profiles which poses a challenge to device retention. Existing attempts to retain these devices often include using bolted connections that rely on thread locking adhesive, nylon locking inserts, or similar thread lockers to keep them from backing off
Mounting small devices such as red dot sights, flashlights, laser beam sights or designators on standard rails such as Picatinny, NATO or other rails often results in disproportionally large mounting mechanics or mounts with retention issues. Large lever locking rail mount designs commonly used to mount large telescopic type sights are sometimes used on small rail mounted devices, defeating the attempt to provide a compact solution. In some designs, mechanical locks are added to prevent loosening of the device. These typically are sliding or rotary keys or tabs that act independently from the mounting mechanics. Large mounting mechanics can be a snag hazard and cause an obstruction to the scene in a sight. More compact rail mounts often have multiple small parts and fasteners that are potential points of failure and increase the cost of the solution. Existing rail mounts typically require the use of thread locking adhesives to mitigate the risk of the mounted device coming loose due to shock or vibration.
Accordingly, there is a need for more reliable, more resilient, and less cumbersome rail mounting systems.
The application, in various implementations, addresses deficiencies associated with existing rail mounts or mounting systems. The application includes exemplary mounts and assemblies that provide reliable and resilient mounting of accessories that are resistant to substantial and repeated shocks produced by a firearm or other device.
This application describes exemplary mounts and assemblies that use the body of the device to thread a clamp screw into or an insert into the body if the body material is not suitable for a threaded interface (e.g., plastic). Female features on the inward side of a head of the clamp screw are equally distributed around its diameter and used to prevent inadvertent rotation. These female locking features match with male locking features on a clamp component in terms of their general size, but more specifically with their respect to their pattern distribution. The angular separation of these features, the pitch of the clamp screw, and the stroke of spring pressure are taken into consideration to ensure optimal performance. In certain implementations, at least one set of these features, either male or female, have a cam angle or similar geometry associated to its interface to allow the clamp screw to be rotated by a user. Cam angles or similar geometry on both sets can improve the design's ease of use and the male/female designation is interchangeable. In some configurations, resilient devices such as disc springs and/or compression springs are installed between the base of the device and the rail clamp. As the clamp screw is rotated to clamp the device to the rail, the rail clamp is drawn in and the spring pressure increased.
In various implementations, the locking features mate and cam apart as the clamp screw is rotated. This camming action causes the rail clamp to move axially while increasing the spring load as the head of the clamp screw rides over the male locking feature. When the locking features align again, the spring pressure is slightly reduced and the engaged features act to lock the rail clamp and clamp screw together to, thereby, prevent unintended rotation. The user can continue to tighten the clamp screw, either by hand or using a tool feature on the screw head, until satisfied with the clamping pressure applied or until the screw no longer indexes. In one configuration, the mechanics will be at the maximum spring force when the clamp screw can no longer be rotated and the locking features are mated.
In some implementations, when the clamp screw has been tightened to secure the device to the rail, a rotation of the clamp screw with enough torque to overcome the increased spring pressure induced by the rail clamp's axial movement is required to loosen the rail mounted device. This has the technical effect of reducing the clamping force only and would need to be repeated multiple times to loosen the device and several times to free the device from the rail.
In various configurations, integral features on the inward side of the clamp screw and outward face of the rail clamp enable part reduction which impacts both the reliability and cost of the clamping solution. Incorporating compression springs into the design improves the ease in which the device is installed and removed from a rail. The use of disc springs allows for a compact design while providing the necessary clamping force to secure the device to the rail and load the locking interface. Threading directly into the base of the device to interface with the clamp screw simplifies the design with a minimum of parts required. Machined features in the base also function to heel the rail clamp as the device is clamped to the rail.
In one aspect, a locking rail mount includes a body arranged to be mounted adjacent to a mounting rail where the mounting rail extends in a first direction and includes a plurality of ties extending at least partially across the rail in a second direction substantially perpendicular to the first direction. The rail mount also includes a clamp screw extending through a channel defined by the body and across the mounting rail in the second direction. The clamp screw includes a screw head having a first surface facing away from the mounting rail and a second surface facing toward the mounting rail. The second surface includes a first plurality of locking elements where each has a first surface relief geometry.
The rail mount further includes a rail clamp arranged to: i) engage with a first end of a first tie of the plurality of ties to hold the body adjacent to the mounting rail; and ii) disengage from the first end of the first tie of the plurality of ties and release the body from adjacent to the mounting rail. At least one compression spring is positioned between the body and the rail clamp. The at least one compression spring applies a compression force that pushes a first surface of the rail clamp toward the second surface of the screw head. The first surface of the rail clamp includes a second plurality of locking elements complementarily arranged with respect to the first plurality of locking elements and having a second surface relief geometry that is complementary and/or opposing to the first plurality of locking elements. When the clamp screw is tightened, the first plurality of locking elements and second plurality of locking elements are aligned to lock the rail clamp and clamp screw together to prevent unintended rotation of the clamp screw.
In some implementations, the body is a portion of an accessory. The accessory may include an optical sight, camera, phone, light, laser, audio sensor, audio emitter, or detachably connectable tool. The surface relief geometry may include a cam angle. The mounting rail may be located on a firearm, helmet, pack, wearable item, or vehicle. At least one compression spring may cause axial movement along the clamp screw as the clamp screw is rotated to either tighten or loosen the rail clamp. The rail mount may include at least one disc spring. The at least one compression spring and the at least one disc spring may cause the axial movement along the clamp screw as the clamp screw is rotated to either tighten or loosen the rail clamp.
In some implementations, the axial movement along the clamp screw as the clamp screw rotates provides a positive tactile interface to a user. The positive tactile interface may reduce the likelihood of the clamp screw being over-tightened to a point of damaging the mechanics of the locking rail mount. In some configurations, when the clamp screw is tightened to secure the body to the rail, a rotation of the clamp screw with enough torque to overcome the increased compression spring pressure induced by the rail clamp's axial movement is required to loosen the rail mounted body.
In another aspect, the above-described locking rail mount is part of a rail mounting assembly where the rail mounting assembly includes a mounting interface arranged to connect an accessory to the rail mounting assembly while the rail mounting assembly uses the locking rail mount to connect to the mounting rail. In a further aspect, a firearm includes the above-described mounting rail, which is arranged to receive a rail mounting assembly having the above-described locking rail mount.
Any two or more of the features described in this specification, including in this summary section, may be combined to form implementations not specifically described in this specification. While aspects of the disclosure may relate to military applications, these aspects can also relate to non-military and commercial applications. For instance, implementations of the compact rail mount or rail mounting assembly may be used with hunting and/or sporting rifles or other non-military firearms. Implementations of the rail mount or rail mounting assembly described herein may be used to mount various types of accessories to various types of structures and/or items. For example, a rail may be implemented on a vehicle such as a car, truck, bicycle, motorcycle, plane, boat, and the like. A rail may be implemented on a helmet, pack, or other wearable items. The type of accessory may include, without limitation, a camera, phone, light, audio sensor, audio emitter, detachably connectable tool, and the like.
The details of one or more implementations are set forth in the accompanying drawings and the following description. Other features and advantages will be apparent from the description and drawings, and from the claims.
Like reference numerals in different figures indicate like elements.
The application, in various implementations, addresses deficiencies associated with existing rail mounting devices and systems. The application includes exemplary devices, systems, and assemblies for providing reliable, resilient, and user-friendly rail mounting techniques.
Innovative aspects of the disclosure include a compact locking rail mount design with a minimum of machined parts required to meet design to cost goals and improve reliability. This robust solution has integral mechanical locking features preventing the device from loosening on the rail when exposed to shock and vibration events without the need for thread locking adhesive. Disc and/or compression springs are used as a resilient feature in conjunction with the mechanical locking features to cause axial movement along the locking screw as the screw is rotated to either tighten or loosen the locking and/or rail clamp. Using axial movement is very desirable as it requires the disc and/or compression spring pressure to be increased to overcome the mechanical lock. The design provides a user with a positive tactile interface reducing the likelihood of the screw being over-tightened to the point of damaging the mechanics of the locking rail mount.
Clamp screw 102 and/or 224 may include screw head 112 having a first surface 218 facing away from mounting rail 108 and a second surface 210 facing toward mounting rail 108. The second surface 210 includes a plurality of locking elements 206, each having a surface relief geometry. Rail clamp 106 is arranged to engage with a first end of tie 214 of the plurality of ties 214 and 220 to hold body 110 adjacent to mounting rail 108 and disengage from the first end of the tie 214 and release body 110 from adjacent to mounting rail 108. Screw head 112 may include tool features 104 that enable operation of the screw 112 using a tool such as a screwdriver.
At least one compression spring 204 is positioned between body 110 and rail clamp 106. The at least one compression spring 204 applies a compression force that pushes a surface 212 and/or 414 of rail clamp 106 toward surface 210 of screw head 112. Surface 212 of rail clamp 106 may include a plurality of locking elements 208 complementarily arranged with respect to a plurality of locking elements 206 on surface 210 of screw head 112 that have a complimentary and/or opposing surface relief geometry to locking elements 208. Locking elements 206 may including male locking elements while locking elements 208 include female locking elements or vice versa. When clamp screw 102 is tightened, the plurality of locking elements 206 and plurality of locking elements 208 are aligned to lock rail clamp 106 and clamp screw 102 together to prevent unintended rotation of clamp screw 102.
The body 110 may be a portion of an accessory such as, without limitation, an optical sight, camera, phone, light, laser, audio sensor, audio emitter, or detachably connectable tool. The surface relief geometry of elements 206 and 208 may include a cam angle. Mounting rail 108 may be located on, without limitation, a firearm, helmet, pack, wearable item, or vehicle. At least one compression spring 204 may cause axial movement along clamp screw 102 as clamp screw 102 is rotated to either tighten or loosen rail clamp 106. Locking rail mount 114 may include at least one disc spring 276.
At least one compression spring 204 and at least one disc spring 276 may cause axial movement along clamp screw 102 as clamp screw 102 is rotated to either tighten or loosen rail clamp 106. The axial movement along clamp screw 102 as clamp screw 102 rotates may provide a positive tactile interface to a user. The positive tactile interface may reduce the likelihood of clamp screw 102 being over-tightened to a point of damaging the mechanics of locking rail mount 114. In some implementations, when clamp screw 102 is tightened to secure body 110 to rail 108, a rotation of clamp screw 102 with enough torque to overcome the increased compression spring pressure induced by the rail clamp's axial movement is required to loosen rail mounted body 110.
In some implementations, locking rail mount 114 is part of a rail mounting assembly where the rail mounting assembly includes a mounting interface arranged to connect an accessory to the rail mounting assembly while the rail mounting assembly uses locking rail mount 114 to connect to mounting rail 108. In one implementation, a firearm includes mounting rail 108 that is arranged to receive a rail mounting assembly having locking rail mount 114.
Elements or steps of different implementations described may be combined to form other implementations not specifically set forth previously. Elements or steps may be left out of the systems or processes described previously without adversely affecting their operation or the operation of the system in general. Furthermore, various separate elements or steps may be combined into one or more individual elements or steps to perform the functions described in this specification.
Other implementations not specifically described in this specification are also within the scope of the following claims.
This application claims priority to and the benefit of U.S. Provisional Patent Application No. 63/185,468, filed on May 7, 2021, entitled “COMPACT LOCKING RAIL MOUNT,” the entire content of which are incorporated herein by reference.
| Number | Date | Country | |
|---|---|---|---|
| 63185468 | May 2021 | US |
