The present invention is a dispenser for applying an adhesive material to a remote surface. In particular, the present invention relates to a dispenser for applying adhesive material to a case mouth and primer of an ammunition round that projects the adhesive through the air.
Dispensing adhesives onto surfaces without contacting the surface with the tip of the dispenser nozzle is difficult because of the characteristics of the adhesives, in particular the low viscosity and the tendency for the adhesive to cure on/in the tip of the nozzle. One application where the application of an adhesive to a surface has been difficult is the case mouth of an ammunition round. Various methods and apparatus have been developed for applying sealant materials to the inside of the case mouth of cartridge cases. The sealant is used to help prevent moisture from getting inside the cartridge case and improves the performance of the bullet in outdoor environments, while also increasing the storage life. The types of sealant material used and the manner in which they are applied affect how the bullet is secured to the cartridge case. The bullet must be securely held in the case mouth of the cartridge case so that it does not fall out during manufacture or when being used and the seal must isolate the interior of the cartridge case from the exterior environment. Preferred sealants provide effective sealing properties and provide sufficient, but not excessive, adhesion between the bullet and the case mouth of the cartridge case.
In the past, the case mouths of cartridge cases have been sealed to prevent moisture infiltration around the bullet by applying a sealant to the inside of the case mouth before beginning other loading operations. Traditionally, the preferred sealant was a black asphaltic tar. It was applied wet and set aside for drying and curing. Once the sealant dried, the frictional heat from seating the bullet partially re-melted the tar, ensuring a good seal. However, this method was time consuming, did not allow high throughputs, and after application the sealant has a short work life, meaning projectiles had to be assembled with a pre-set time or they would not seal.
There is no proven method in the prior art for applying an anaerobic adhesive to an ammunition case mouth and primer. Various attempts have been made to use touch transfer dispensing methods to apply the sealant to the case mouth. However, touch transfer has not been found to be an optimal method for several reasons. First, when dispensing on the primer, the dispenser must be carried out with the bullet in a horizontal position. This requires a mechanism that slides in and out as the bullet passes by on a conveyor and greatly reduces throughput potential. Second, anaerobic adhesives begin to cure when they contact metal. Thus, anaerobic adhesives used with a touch transfer method begin to cure when the dispenser tip contacts the active metals (i.e., brass and copper) of the bullet. This reduces throughput and current touch transfer methods typically produce no more than 200 rounds per minute. Accordingly, there is a need for a dispenser system with increased throughput, wherein the adhesive does not contact the bullet when the adhesive is in the dispenser.
In accordance with the present invention, a dispenser for dispensing an adhesive onto a remote surface is provided. The dispenser includes a reservoir containing an adhesive; a positive displacement pump; and a nozzle having a tapered tip. The positive displacement pump delivers a predetermined amount of the adhesive, preferably an anaerobic adhesive, from the reservoir to the nozzle at predetermined intervals. The nozzle can have at least a 27 gauge discharge port for discharging the predetermined amount of adhesive through the air and onto the case mouth and primer ammunition. Preferably, the distance between the discharge port of the nozzle and the surface is at least 1/16-inch. The positive displacement pump is preferably a rotary pump and operates at a speed of from 1,400 to 1, 500 rpm.
The preferred embodiments of the dispenser of the present invention, as well as other objects, features and advantages of this invention, will be apparent from the accompanying drawings wherein:
The present invention is a dispenser (also interchangeably referred to herein as “the dispenser” or “the dispenser system”) used for dispensing of adhesives, preferably light curing anaerobic adhesives having viscosities of 30-45 cps, onto remote surfaces. As used herein, the term “remote surfaces” refers to any surface not in contact with the dispenser that can be bonded to another surface by an adhesive, wherein the surface can include metal, plastic, wood and synthetic and composite materials. The dispenser system preferably dispenses an anaerobic sealant or adhesive (e.g., Loctite® 190700 CMS) onto a remote surface. In preferred embodiments, the anaerobic sealant is dispensed onto the surface of a case mouth and primer ammunition round. Anaerobic adhesives begin to cure when they come in contact with a metal and the absence of air. The dispenser “shoots” adhesive approximately 1/16″ from the discharge port in the nozzle tip to the remote surface without the nozzle tip contacting the remote surface, preferably the case mouth and the primer of the bullet. This dispenser uses a rapid fire through the air technique that overcomes the problems encountered by touch transfer dispenses, wherein the tip contacts the surface. By “shooting” the adhesive through the air, the dispenser system eliminate the potential to contaminate the dispenser tip by eliminating contact of the tip with active metals on the surface.
The dispenser system includes an adhesive, a first conduit for supplying the adhesive to a pump and a second conduit connecting the pump discharge to a nozzle through which the adhesive is dispensed. The adhesive can be stored in a reservoir or a cartridge and delivered to the pump using well known methods, such as pressurizing the reservoir/cartridge to force the adhesive to flow to the pump or using a plunger/rod assembly to push the adhesive out of the reservoir/cartridge. The pump delivers a predetermined amount of adhesive to the nozzle with sufficient pressure so that, when the adhesive exits the nozzle, it travels through the air and onto the bullet. The nozzle preferably has a tapered needle tip that provides back pressure and helps to direct the adhesive. The discharge port of the tapered needle tip has a diameter of 25 gauge or larger, preferably about 27 gauge. The tapered tip needle has been found to provide more accurate and reliable dispensing.
The pump is preferably a positive displacement pump that can be adjusted to discharge specific volumes of adhesive according to the user's application. Positive displacement pumps are well known to those skilled in the art and they deliver a definite volume of liquid for each cycle of pump operation. This volume is constant regardless of the resistance to flow offered by downstream components in the system up to the rated capacity of the pump. A positive displacement pump cyclically delivers liquid in separate volumes with no delivery in between. This allows the cycles to correspond to the bullets that are sequentially placed in front of the nozzle. As the pump shaft rotates, a notched portion of the pump head displaces the fluid from one side of the pump to the other. This motion is what shoots the adhesive through the air and onto the bullet.
The positive displacement pump operates at speeds of from 0 to 1,500 rpm, preferably 1,200-1,500 rpm and most preferably between 1,400 and 1, 500 rpm. The most preferred positive displacement pumps for the dispenser system are rotary positive displacement pumps. The dispenser system of the present invention can increase throughput from about 200 rounds per minute for prior art methods to about 400 rounds per minute using a single dispenser.
The dispenser system deposits an anaerobic adhesive onto a bullet without the dispenser tip contacting the remote surface. This eliminates the problems in the touch transfer method caused when the adhesive began to cure upon contacting a metal surface, such as the surface of an ammunition round. Instead, the dispenser tip is positioned a distance from the surface and shoots adhesive through the air (about 1/16″ or more) from the tip to the bullet case mouth and primer. This eliminates the need for a mechanism that slides in and out and provides increased throughput potential. When dispensed onto an ammunition round, the anaerobic adhesive travels through the air and contacts either the case mouth or primer and wicks around the surfaces. Because the tip of the dispenser nozzle does not contact the bullet, the adhesive does not begin to cure and clog the dispenser tip due to contact with active metals. This allows the dispenser system to operate at high speeds of up to 400 parts per minute.
Referring now to the figures,
The examples set forth below serve to provide further appreciation of the invention but are not meant in any way to restrict the scope of the invention.
An ammunition customer would like to dispense anaerobic onto ammunition case mouth and primer at a rate of 400 bullets per minute with few dispensing points as possible. Touch transfer simply is not fast enough. The dispenser system is used to dispense adhesive through the air (i.e., “shooting”) onto the bullet, which allows the customer to gain the required process speed. The dispenser is capable of dispensing at a rate of 400 bullets per minute using 1 dispense point.
A customer wishes to positively dispense anaerobic adhesive onto the case mouth or primer of a round. Current methods for dispensing onto ammo rounds are based on pressure timed system dispenser, which is rate limiting and accuracy limiting. The dispenser system uses a positive displacement pump to dispense a predetermined amount of adhesive onto the case mouth and satisfy the customers requirements.
The dispenser system eliminates touch transfer from the dispense method and reduces the potential for the dispenser tip to clog/cure over time as the adhesive contacts the metal of the bullet.
Thus, while there have been described the preferred embodiments of the present invention, those skilled in the art will realize that other embodiments can be made without departing from the spirit of the invention, and it is intended to include all such further modifications and changes as come within the true scope of the claims set forth herein.
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