Annealing system for ammunition casings using induction heating

Abstract

A system for annealing brass ammunition casings uses induction heating. Casings are continuously fed in series through a rotating tube within a solenoid induction coil.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to the field of annealing systems for ammunition casings. More specifically, the present invention discloses an annealing system for ammunition casings using induction heating.

2. Statement of the Problem

One of the time-consuming and costly steps in ammunition manufacturing is the annealing process. Annealing is necessary to reduce work hardening caused by various forming steps during manufacturing. The conventional approach has been to anneal brass in batches in a pit furnace. Each batch typically takes many hours (e.g., about eight hours) to ensure that the inner-most parts in the pit furnace reach the annealing temperature. Batch processing limits through-put and makes it more difficult to efficiently integrate the annealing process with the other steps in the manufacturing process that are designed for steady production over the work day.

The long processing times required for annealing with a pit furnace also promote oxidation of the brass. In some cases, an inert gas is introduced to reduce oxidation. However, in any case, the parts must be washed in sulfuric acid after annealing to remove oxidation. Product losses of up to 1% by weight are common. In addition, the effort and expense of handling sulfuric acid and disposing of the resulting waste products can be significant.

Furthermore, the large size and thermal mass of a conventional pit furnace cause wide variations in the annealing times and temperatures that parts experience based on their locations within the pit furnace. Those parts closest to the heating elements in the pit furnace are annealed at higher temperatures and for a longer time than parts located away from the heating elements. This results in wide variations in part quality because it is nearly impossible to control variations in hardness.

Finally, conventional pit furnaces require large amounts of electricity and are not very energy efficient. For example, one type of conventional pit furnace requires 45 KW of electricity. The entire thermal mass of the pit furnace and its contents must be heated to the annealing temperature and held at this temperature for many hours. At the end of the annealing cycle, the pit furnace must be allowed to cool over a significant period of time, and all of this thermal energy simply dissipates into the ambient environment. Therefore, a need exists for an annealing system for brass ammunition casings that addresses these shortcomings. It should be expressly understood that the term “casings” should be broadly construed in the present application to include cups and other forms of work in progress.

Prior Art.

The prior art in the field also includes the following:

	Inventor	Patent No.	Issue Date
	Distler	2,907,858	Oct. 6, 1959
	Carbo	2,937,017	May 17, 1960
	Carbo	3,005,894	Oct. 24, 1961
	Armstrong	3,829,650	Aug. 13, 1974
	Mucha et al.	4,090,698	May 23, 1978
	Pryor et al.	4,494,461	Jan. 22, 1985
	Pryor et al.	4,594,117	Jun. 10, 1986
	Pryor et al.	4,638,535	Jan. 27, 1987

Mucha et al. disclose a system for inductively heating elongated work pieces, such as shell casings. Two multi-turn induction heating coils are axially aligned. The work pieces pass in sequence along a passage through both heating coils. An indexing system is used to maintain spacing between work pieces.

Distler discloses another example of a system for treating shell casings using induction heating.

The Carbo patents disclose a system for hardening shell casings that uses a bonnet-type induction heating coil.

Armstrong discloses another example of a system for hardening shell casings using an induction heating tunnel. The patents issued to Pryor et al. are only of passing interest.

Solution to the Problem.

Nothing in the prior art discussed above shows an annealing system for annealing in which brass ammunition casings pass in series through a rotating tube within a solenoid induction coil. This approach produces a continuous stream of annealed parts more rapidly with uniform hardness characteristics and minimal oxidation. In addition, the solenoid induction coil generates heat only in the area of the casings, which significantly reduces electrical consumption.

SUMMARY OF THE INVENTION

This invention provides an annealing system for brass ammunition casings using induction heating. In particular, casings are continuously fed in series through a rotating tube within a solenoid induction coil.

These and other advantages, features, and objects of the present invention will be more readily understood in view of the following detailed description and the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention can be more readily understood in conjunction with the accompanying drawings, in which:

FIG. 1 is a cross-sectional diagram of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Turning to FIG. 1, a cross-sectional view is shown of the present invention. A continuous series of brass cartridge casings are fed from the left side of the drawing by means of a dual belt feed system 10. Other types of feeder mechanisms could be readily substituted. The feed rate of the casings can be monitored by an encoder 12.

The casings are heated to the annealing temperature by induction of eddy currents as they pass along the central axis of the solenoid induction coil 30. For example, an induction coil with a length of about 24 inches and a power rating of approximately 10 kilowatts is sufficient to anneal a stream of typical casings in about 10 to 15 seconds. The solenoid induction coil 30 has a generally helical winding surrounding a hollow central passageway extending along the central axis of the induction coil 30.

A rotating quartz tube 20 is used as a conduit for the casings as they pass through the induction coil 30. Quartz is relatively chemically inert and has a high melting point. Other materials with suitable physical properties could be readily substituted, such as a ceramic material. Preferably, the quartz tube 20 extends along the central axis within the passageway of the induction coil 30 so that the casings within the tube 20 pass along the most concentrated region of the electromagnetic field created by the induction coil 30. The quartz tube 20 preferably has an inside diameter slightly larger than the outside diameter of the casings. This maintains a uniform alignment of the casings roughly parallel to the longitudinal axis of the tube 20.

As shown in FIG. 1, the quartz tube 20 is supported at one end by a mounting collet 24 attached to a drive tube 22 driven by a motor (not shown). Rotation of the tube 20 about its longitudinal axis achieves a number of objectives. First and foremost, it helps to prevent casings from sticking to the wall of the tube or to one another, thereby keeping the casings moving along the length of the tube. It also helps to ensure even heating and annealing by tumbling the casings radially as they slide along the tube. Optionally, additional steps can be taken to prevent contact welding between adjacent casings. For example, glass marbles or other suitable insulating spacers can be inserted between the casings. A slight taper (e.g., approximately 0.002 inches per inch) can be ground into the inside diameter of the quartz tube 20 to help ensure relative movement between adjacent casings.

An infrared probe 40 monitors the temperature of the casings emerging from the quartz tube 20. This temperature sensor 40 can be used to regulate the power output of the induction coil, and thereby control the annealing temperature of the casings.

The present invention uses less electrical energy than a conventional pit furnace of comparable capacity. A 45 KW pit furnace running on an eight-hour cycle consumes more energy in the first two hours than a 10 KW induction coil in the present system consumes in the full eight hours. After the pit furnace comes up to full temperature, it will cycle on and off for the remaining six hours at about 40% of its full load rating, thus consuming additional electrical energy. In contrast, the present system requires far less electrical energy by heating only the brass cups and the adjacent region within the quartz tube. Each part receives the same amount of energy to exactly the same depth, thereby assuring uniform hardness. A very large portion of this thermal energy can be reclaimed by means of a heat exchanger and used in the subsequent acid etching process.

The rapid annealing times achieved by the present invention allow only minimal oxidation of the parts. In turn, this allows the use of a much milder acid wash and results in almost no loss of weight by the parts. For example, a relatively dilute solution of phosphoric acid can be employed in place of sulfuric acid.

The present system also allows on-demand annealing instead of batches once a day. This allows both the pre-annealing and post-annealing processes to be performed on a continuous basis. This simplifies scheduling and reduces lead times between operations in the manufacturing process.

The above disclosure sets forth a number of embodiments of the present invention described in detail with respect to the accompanying drawings. Those skilled in this art will appreciate that various changes, modifications, other structural arrangements, and other embodiments could be practiced under the teachings of the present invention without departing from the scope of this invention as set forth in the following claims.

Claims

1. An annealing system for ammunition casings comprising: an induction coil; a rotating tube extending within the induction coil; and a feeder mechanism feeding a series of casings through the induction coil at a predetermined rate to result in a predetermined residence time within the induction coil and annealing temperature for the casings.

2. The annealing system of claim 1 wherein the rotating tube is comprised of quartz.

3. The annealing system of claim 1 wherein the rotating tube is comprised of ceramic.

4. The annealing system of claim 1 wherein the induction coil comprises a solenoid induction coil.

5. The annealing system of claim 1 further comprising a temperature sensor monitoring the temperature of the annealed casings exiting the rotating tube.

6. The annealing system of claim 5 wherein the temperature sensor is used to regulated the power output of the induction coil to thereby control the annealing temperature of the casings.

7. The annealing system of claim 1 wherein the induction coil further comprises a central axis, and wherein the rotating tube extends along the central axis of the induction coil.

8. The annealing system of claim 1 further comprising a series of insulating spacers inserted between casings entering the rotating tube.

9. The annealing system of claim 1 wherein the inside diameter of the rotating tube is slightly larger than the outside diameter of the casings.

10. A method for annealing ammunition casings comprising: providing an induction coil having a central axis; providing a tube extending along the central axis of the induction coil; rotating the tube; and feeding a series of casings through the tube at a predetermined rate to result in a predetermined residence time within the induction coil and annealing temperature for the casings.

11. The annealing system of claim 10 wherein the induction coil is a solenoid induction coil.

12. The annealing system of claim 10 further comprising inserting insulating spacers between casings entering the rotating tube.

13. The annealing system of claim 10 further comprising monitoring the temperature of the annealed casings exiting the rotating tube.

14. The annealing system of claim 13 further comprising regulating the power output of the induction coil based on the measured temperature of the annealed casings exiting the rotating tube.

15. An annealing system for ammunition casings comprising: a solenoid induction coil having a central axis with a central passageway; a rotating tube extending within the central passageway parallel to the central axis of the induction coil; and a feeder mechanism feeding a series of casings through the induction coil at a predetermined rate to result in a predetermined residence time within the induction coil and annealing temperature for the casings.

16. The annealing system of claim 15 wherein the rotating tube comprises quartz.

17. The annealing system of claim 15 wherein the rotating tube comprises ceramic.

18. The annealing system of claim 15 wherein the rotating tube has an inside diameter slightly larger than the outside diameter of the casings.

19. The annealing system of claim 15 further comprising a series of insulating spacers inserted between casings entering the rotating tube.

20. The annealing system of claim 15 further comprising a temperature sensor monitoring the temperature of the annealed casings exiting the rotating tube.