Loading Accessories | Loading the Rifle | Shooting Pointers | Casting Bullets
Bullets used are either groove-lubricated or paper patched lead or lead alloy projectiles. They may be cast and directly used, or if paper patched, may be cast as slugs and then put into a hammer or press swage for final shaping. If the bore is cleaned after each shot, bullets of .001 inch (diameter) oversize may be loaded. The most suitable size, however, is a bullet that is bore diameter or .001 inch undersize. When fired, obturation of the base prevents gas blow-by and consequent inaccuracy.
Bullet shape varies widely, and the best shape for each rifle must be determined by experimental shooting. Flat-nose bullets may shoot as well as round-nose ones. Some have experienced difficulty in getting the sharp-or pointed-nose bullets to perform satisfactorily, especially in barrels with a rifling pitch slower than one turn in twenty inches.
Grooved bullets are best made from a mould that produces bullets that do not require sizing to bring them to proper diameter. The custom moulds produced by Paul Jones and other makers produce good bullets. Standard moulds from Lyman, NEI, and Dixie Gun Works (Pedersoli made) are good if the correct size is available from their product line. Sizing down .458 inch diameter bullets to .450 inches may distort the bullet enough to ruin its accuracy potential.
Weight for .45 caliber bullets may range from 480 grains to 570 grains. Obturation or bump-up of the bullet is very dependent on the bullet's weight and the hardness of the lead or lead-alloy used. The bullet must upset a sufficient amount from the impulse of the burning powder to seal the gas pressure and ride the bore interior to provide accuracy. Match-grade bullets should not vary more than one grain in weight.
Bullet base shape also varies greatly. Some of the most common shapes (in longitudinal cross-section) are shown below:
|Bullet Base Shape Varieties|
Paper-patched bullets present unique loading problems. The paper MUST stay in place on the bullet during loading; thus a clean bore is essential. Paper thickness may be varied to provide different tightness of fit of the bullet to the bore. Use of light, thin air-mail paper (.0015 inch thick) has worked well in several rifles. A thin coat of grease, sperm oil, light-weight petroleum oil, or a synthetic lubricant should be applied to the paper immediately prior to loading.
A muzzle-loaded bullet of lesser diameter than the bore is susceptible to gas leakage when fired. To help assure that gas does not pass between the side of the bullet and the bore, a sealing wad is sometimes used. The original British target rifles were loaded using a paper-wax-paper wad under the bullet. Wads approximately 3/l6-inch thick and fabricated from pure hair felt may be used either dry or saturated in wax lubricant. Thin, solid cardboard wads may also be used. One of the best wad materials is 1/16-inch-thick, low-density polyethylene sheet. The wads should be cut using a press or drill press, as hammer-cut wads tend to be cut crooked. OxYoke commercial wads are excellent for bullet sealing wads.
Wads should be of groove size or up to .004 inch larger to ensure sealing. Wad cutters made from heat-treated, oil-hardened tool steel work well when used in a drill press. Parker-Hale-manufactured Whitworth rifles were furnished with a hexagonal wad cutter to match the bore.
Wads improve the gas seal; thus gas pressure is higher than without a wad. Consequently, bullet velocity is higher, and bullet impact at the target is usually higher. The plastic wads seal better than felt wads if they are sized properly for the bore. Bullets with recessed bases or cavities do not lend themselves to wad usage. The wad folds up into the base cavity and may not perform its intended function.