Gun barrels must be kept as clean as possible for reliable operation of the firearm. Use in extreme environments and in combat presents multiple opportunities for dirt and debris to enter the barrel through the muzzle and thereby foul the weapon. This can result in permanent damage to the interior surface of the barrel and/or disabling of the gun. Because gun muzzles heat to very high temperatures during use, particular in semi and fully automatic firing modes, it has not been practical to cover or protect the barrel particularly at the muzzle end.
The present disclosure and related inventions provides gun barrel caps which fit tightly and securely upon a wide variety of gun barrels at the muzzle to fully protect the barrel from contaminants entering the barrel, and to protect operators from burns from the muzzle after firing. The barrel caps are preferably made of high strength and high temperature resistant polymeric material, and may be molded of a polymeric material and preferably an elastic polymer or “elastomer” and thermoplastic elastomers which exhibit viscoelasticity in durometers in the approximate hardness ranges of, for example, 5 Shore A to 90 Shore A, 40 Shore A or lower and up to 80 Shore A, and a more preferred range of 40 Shore A to 70 Shore A, and an even more preferred range of 50 Shore A to 70 Shore A, and an even more preferred range of 35 Shore A to 60 Shore A. Such materials include, for example, one or more of the following: synthetic rubber, natural rubber, neoprene, butyl rubber, silicone, urethane, viscoelastic urethane, nylon, PVC, polyethylene, polystyrene, polypropylene, PVB, PVDF or Nanbrol®, a nano-particle reinforced nitrile butadiene rubber (NBR), and thermoplastic polymer alloys with SBR, EPDM or urethanes as base polymers and blended to optimize dynamic properties, dimensional stability and elasticity, thermal resistance and fatigue performance. Additives which can be used with these materials in the manufacture of the gun barrel caps of the present disclosure include glass beads, Expandacel™, Kevlar™, Mylar™, fiberglass, cotton or other woven or non-woven materials in internal layers with the gun barrel caps. Additives or coatings (such as for example Nomex™ or Nitrile™) can be selectively incorporated into the gun rail attachment body material or design for improved heat resistance, durability, strength, tackiness or surface friction, or any other desired properties.
The use of thermoplastic polymers in these hardness ranges for gun barrel caps and components has numerous advantages, a principal one of which is a far superior gripping structure and feel than the relatively much harder rail cover attachments of the prior art. The use of viscoelastic materials in the disclosed hardness ratings provides numerous advantages over the much harder plastic rail covers of the prior art. The gun barrel caps provide a gripping structure and surface which can be squeezed as a relatively soft grip over the barrel muzzle, dramatically improving the secure handling of a gun and provide shock and recoil absorption, vibration dampening—including automatic or semi-automatic fire recoil and recoil vibration, resistance to moisture and grease, a high friction gripping surface even when wet, temperature insulation, reduction of infra-red signature and mirage effect, sound insulation and noise reduction and cushioning, an improved mounting surface for the gun barrel, protection against operator burns, damage protection for the gun, and other advantages and benefits as further described herein. A preferred material compound resists extreme heat and cold temperature fluctuations and will maintain its flexibility and tactile feel in a wide range of environments. The gun barrel caps made of the disclosed materials have superior thermal insulative properties and can withstand when mounted on a rail on a gun radiated barrel temperatures as high as 1500 degrees F. or higher. When installed on one or more rails of a gun, the attachments 10 effectively and substantially reduce heat transfer and the infrared heat signature of the gun during and after firing as a result of the insulative properties.
As shown in the accompanying
A first group of axially aligned and radially arrayed ridges 110 are formed to extend from the interior surface 104 of the cylindrical wall 102. Each ridge 110 has an apex 111 which provides a contact surface for the exterior of a gun barrel at the muzzle, as illustrated. The multiple contact areas 111 of the ridges 110 provide a combined gripping contact with a gun barrel B of a gun G so that the barrel cap 100 is thereby tightly secured upon the barrel.
A second group of axially aligned and radially arrayed ridges 120 are formed to extend from the exterior surface 103 of the cylindrical wall 102. The ridges 120 provide a positive tactile contour to the exterior of the barrel cap 100 for manipulation for installing and removing the barrel cap 100 from a barrel muzzle. Also, the extension of the end wall 105 beyond the cylindrical wall 102 and the ridges 120 provides a gripping structure for manipulating the barrel cap 100 upon installation and removal. As shown in
An internal pilot plug 108 can be formed on an interior side of the end wall 105 and within the cylindrical wall 102 for fitment within the opening at the muzzle end of the barrel to provide even tighter engagement of the barrel cap 100 with a barrel.
This application is related to U.S. provisional patent application No. 61/909,132, filed Nov. 26, 2013.
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Number | Date | Country | |
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20150308781 A1 | Oct 2015 | US |
Number | Date | Country | |
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61909132 | Nov 2013 | US |