This invention relates to nodular nickel boron coatings on surfaces that requires a low coefficient of friction as well as a superior wear resistance. These coatings can be used as an improved substitute for wet lubricants. A lubricant can be incorporated in the nickel boron coating or can be coated onto the nickel boron coating. The final coatings provide improved wear resistance, corrosion resistance and lubricity.
Nickel boron coatings have been described in U.S. Pat. Nos. 6,319,308; 6,066,400 and 5,019,163. These references are incorporated by reference. Usually an electroless coating process as shown in these patents is used to make these coatings. These coatings have a nodular and columnar structure. U.S. Pat. No. 6,319,308 teaches that a lubricant particle can be co-deposited with the nickel boron coating.
The prior art has used wet lubricants to reduce the coefficient of friction and to reduce corrosion in firearms. Usually firearms need to be cleaned and greased on a regular basis after firing. If not regularly greased, the firearm might jam or misfire.
The use of wet lubricants presents a problem for soldiers in the military. Wet lubricants attract grit or sand causing the firearms to jam requiring increased maintenance.
Phosphate reduced electroless coatings have been used on metal substrates such as firearms, to enhance corrosion resistance. These coatings do not possess the wear resistance and lubricity of the nodular nickel boron coatings.
An objective of the invention is to provide dry nodular nickel boron coating having improved lubricity. Another objective of this invention is to provide a substitute for wet lubricants, especially for firearms. Firearms as used in this application cover all types of weapons that use gun powder including rifles cannons and artillery. One objective being to increase the interval needed for reapplying the lubricant to the firearm parts.
The invention is directed to a nodular nickel boron coating having lubricating properties. Nodular and columnar boron coatings made by the above methods disclosed in the above patents have a low coefficient of friction. The above process results in a columnar structure with nodules in the surface layer. Nodules can be produced in other nickel coatings by blasting the surface with hard particles to form the nodules. Using blasting to form the nodules produces an inferior coating in contrast to the electroless nickel boron coatings having a columnar structure.
A lubricant can be introduced to the nickel boron coating by co-depositing a lubricant particle with the nickel boron or after treating the nickel boron coating with a dry lubricant. A variety of techniques exist for the treatment such as blasting the lubricant into the coating with high pressure or burnishing the dry lubricant into the nickel boron surface with a tumbling bowl or by rubbing the dry particle into the nickel boron surface. Examples of dry lubricants are tungsten disulfide or moly disulfide or PTFE (Teflon, trademark)).
The coating composition is useful for substrates that need lubricity as well as wear resistance such as mating surfaces. The firearm industry has a need for these coating compositions. These coatings would allow firearms to be used with a longer maintenance schedule that is required when using the recommended conventional wet lubricants. The maintenance schedule established by firearm manufactures usually instruct users that the guns have be cleaned and then reassembled with fresh grease and oil after every 1000 rounds to prevent corrosion and lock up of the firing mechanisms.
By applying the nodular nickel coating parts to the surfaces of mating components the wear life of the components can be extended beyond the wear life provided by wet lubricants. Firearm components are one example of mating surfaces that would benefit from nodular nickel coatings.
Another problem with wet lubricants is that dusts and grime and sand easily attach. This increases the need for cleaning and re-greasing in unfriendly environments.
Also the continuous firing of rounds wears out the barrel of guns and rifles. These coatings extend the wear of the barrels and acts as sacrificial coating. By acting as a sacrificial coating the barrels can be re-plated allowing the barrel to be reused.
The following experiments were done to show the effectiveness of the these coatings:
Weapon preparation for plating:
Test firing schedules; At times, an inexpensive ammunition was intentionally used because they are known to be damaging to weapon surface finishes by means of corrosive gun powder residue. If this residue isn't thoroughly removed from all surfaces, the residual material becomes acidic and attacks the base metal of the weapon. An objective of this invention is protecting a gun surface with nickel boron from this chemical attack is.
Two test guns were reassembled but one was first burnished with a molly disulfide compound as a dry film lubricant on top of the nickel boron coating. The gun without moly lubrication was at first a little “sticky” and rough in operation but eventually operated as well as the weapon with the dry film lubrication. Extra polishing was required in the breach area of the barrel to prevent the ammunition from hanging-up as it tried to discharge the casing in the non lubricated gun.
The first test firing cycle was as follows, 470 rounds of Winchester ammo was fired in both semi and full automatic mode without incident. The guns were left as fired with no cleaning as is normally done and required by the manufacture. The same day, but 8 hours later, an additional 500 rounds of Wolf Brand ammunition were fired as above without incident or cleaning before, during or after firing. 24 hours later, additional 1200 rounds were fired and again without incident and again the weapons were stored without cleaning. 2 days later, the weapons 500 rounds were fired. The following week, the weapons were again fired, 2000 rounds total with 3 miss-fires that were related to a poor quality magazine, completely unrelated to the function of the gun and it's coated parts.
Both weapons have fired a total of 4670 rounds total. The only miss fires occurred in the initial start-up of the gun without the moly disulfide dry lubrication. Since then, this gun has been incident free. The dry film lubricated gun was had 3 misfires that occurred around 2100 round count due to the poor magazine.
These examples show that the maintenance schedule required by wet lubricants can be greatly extended using these coatings.
This nodular coating forms a self-lubricating firearm. A self-lubricating firearm means a firearm having at least one component with a nodular nickel coating. The properties of the coating include satisfying the need for a wet lubricant, extending the cleaning interval and extending the life of the barrel.
The preferred surface roughness for these coatings on firearm components should be about 20 RMS. The coating after an electroless nickel boron deposition usually has surface roughness of about 40 RMS. A lower RMS is usually needed to reduce the wear between mating surfaces and to prevent unwanted particles like sand from being trapped between the nodules. The surface roughness can be reduced using conventional polishing techniques.
The boron content of the coating should be over 2.5%. and not exceeding 6% As the boron content increase the hardness increases. The preferred range is 4-4.5% by weight
Applying a mixture of tungsten disulfide and moly disulfide 80:20% or 20:80% by weight or volume to a nodular nickel coating enhance the nickel boron coating. About a 50:50 mixture is preferred. These ingredients have uniquely different structure and properties that compliment each other. The mixture can be applied as follows.
This is a continuation of prior U.S. application Ser. No. 10/868,889 filed Jun. 17, 2004 which is a divisional of application Ser. No. 10/316,108 filed Dec. 13, 2002
Number | Date | Country | |
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Parent | 10316108 | Dec 2002 | US |
Child | 10868889 | Jun 2004 | US |
Number | Date | Country | |
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Parent | 10868889 | Jun 2004 | US |
Child | 11711634 | Feb 2007 | US |