A modern knife consists of: • the
blade • the
handle • the
point – the end of the knife used for piercing • the
edge – the cutting surface of the knife extending from the point to the heel • the
grind – the
cross section shape of the blade • the
spine – the thickest section of the blade; on a single-edged knife, the side opposite the edge; on a two-edged knife, more toward the middle • the
fuller – a groove added to make the blade lighter (optional) • the
ricasso – the flat section of the blade located at the junction of the blade and the knife's bolster or guard (optional) • the – the barrier between the blade and the handle which prevents the hand from slipping forward onto the blade and protects the hand from the external forces that are usually applied to the blade during use (optional) • the
hilt or
butt – the end of the handle used for blunt force • the
lanyard – a strap used to secure the knife to the wrist (optional) The blade edge can be plain or
serrated, or a combination of both. Single-edged knives may have a
reverse edge or
false edge occupying a section of the spine. These edges are usually serrated and are used to further enhance function. The handle, used to grip and manipulate the blade safely, may include a
tang, a portion of the blade that extends into the handle. Knives are made with partial tangs (extending part way into the handle, known as "stick tangs") or full tangs (extending the full length of the handle, often visible on top and bottom). There is also the
enterçado construction method present in antique knives from Brazil, such as the
Sorocaban Knife, which consists in riveting a repurposed blade to the ricasso of a bladeless handle. The handle may include a bolster, a piece of heavy material (usually metal) situated at the front or rear of the handle. The bolster, as its name suggests, is used to mechanically strengthen the knife. -made full-
tang survival knife. The metal from the blade extends into the handle.
Blade Knife blades can be manufactured from a variety of materials, each of which has advantages and disadvantages.
Carbon steel, an alloy of
iron and
carbon, can be very sharp. It holds its edge well, and remains easy to sharpen, but is vulnerable to rust and stains. Stainless steel is an alloy of iron,
chromium, possibly
nickel, and
molybdenum, with only a small amount of carbon. It is not able to take quite as sharp an edge as carbon steel, but is highly resistant to corrosion.
High carbon stainless steel is stainless steel with a higher amount of carbon, intended to incorporate the better attributes of carbon steel and stainless steel. High carbon stainless steel blades do not discolor or stain, and maintain a sharp edge.
Laminated blades use multiple metals to create a layered structure, combining the attributes of both. For example, a harder, more brittle steel may be pressed between an outer layer of softer, tougher stainless steel to reduce vulnerability to corrosion. In this case, however, the part most affected by corrosion, the edge, is still vulnerable.
Damascus steel is a form of
pattern welding with similarities to laminate construction. Layers of different steel types are welded together, but then the stock is manipulated to create patterns in the steel.
Titanium is a metal that has a higher strength-to-weight ratio and more flexible than steel. Although less hard and unable to take as sharp an edge, carbides in the titanium alloy allow them to be heat-treated to a sufficient hardness.
Ceramic blades are hard, brittle, lightweight, and do not corrode: they may maintain a sharp edge for years with no maintenance at all, but are fragile and will break if dropped on a hard surface or twisted in use. They can only be sharpened on silicon carbide sandpaper and appropriate grinding wheels.
Plastic blades are not sharp and are usually
serrated to enable them to cut. They are often disposable. Steel blades are commonly shaped by
forging or stock removal. Forged blades are made by heating a single piece of steel, then shaping the metal while hot using a hammer or press. Stock removal blades are shaped by grinding and removing metal. With both methods, after shaping, the steel must be
heat treated. This involves heating the steel above its critical point, then
quenching the blade to harden it. After hardening, the blade is
tempered to remove stresses and make the blade tougher. Mass manufactured kitchen cutlery uses both the forging and stock removal processes. Forging tends to be reserved for manufacturers' more expensive product lines, and can often be distinguished from stock removal product lines by the presence of an integral bolster, though integral bolsters can be crafted through either shaping method. Knives are sharpened in various ways. Flat ground blades have a profile that tapers from the thick spine to the sharp edge in a straight or
convex line. Seen in cross section, the blade would form a long, thin triangle, or where the taper does not extend to the back of the blade, a long thin rectangle with one peaked side. Hollow ground blades have
concave, beveled edges. The resulting blade has a thinner edge, so it may have better cutting ability for shallow cuts, but it is lighter and less durable than flat ground blades and will tend to bind in deep cuts. Serrated blade knives have a wavy, scalloped or saw-like blade. Serrated blades are more well suited for tasks that require aggressive 'sawing' motions, whereas plain edge blades are better suited for tasks that require push-through cuts (e.g., shaving, chopping, slicing). Many knives have holes in the blade for various uses. Holes are commonly drilled in blades to reduce friction while cutting, increase single-handed usability of pocket knives, and, for butchers' knives, allow hanging out of the way when not in use.
Fixed-blade features A fixed blade knife, sometimes called a
sheath knife, does not fold or slide, and is typically stronger due to the tang, the extension of the blade into the handle, and lack of moving parts.
Folding blade features A folding knife connects the blade to the handle through a
pivot, allowing the blade to fold into the handle. To prevent injury to the knife user through the blade accidentally closing on the user's hand, folding knives typically have a locking mechanism. Different locking mechanisms are favored by various individuals for reasons such as perceived strength (lock safety), legality, and ease of use. Popular locking mechanisms include: •
Slip joint – Found most commonly on traditional pocket knives, the opened blade does not lock, but is held in place by a spring device that allows the blade to fold if a certain amount of pressure is applied. •
Lockback – Also known as the
spine lock, the lockback includes a pivoted latch affixed to a spring, and can be disengaged only by pressing the latch down to release the blade. •
Linerlock – Invented by
Michael Walker, a Linerlock is a folding knife with a side-spring lock that can be opened and closed with one hand without repositioning the knife in the hand. The lock is self-adjusting for wear. •
Compression Lock – A variant of the Liner Lock, it uses a small piece of metal at the tip of the lock to lock into a small corresponding impression in the blade. This creates a lock that does not disengage when the blade is torqued, instead of becoming more tightly locked. It is released by pressing the tab of metal to the side, to allow the blade to be placed into its groove set into the handle. •
Collar lock – found on
Opinel knives. •
Button Lock – Found mainly on automatic knives, this type of lock uses a small push-button to open and release the knife. •
Axis Lock – A locking mechanism patented by
Benchmade Knife Company until 2020. A cylindrical bearing is tensioned such that it will jump between the knife blade and some feature of the handle to lock the blade open. •
Arc Lock – A locking mechanism exclusively licensed to
SOG Specialty Knives. It differs from an axis lock in that the cylindrical bearing is tensioned by a rotary spring rather than an axial spring. •
Ball Bearing Lock – A locking mechanism exclusively licensed to
Spyderco. This lock is conceptually similar to the axis and arc locks but the bearing is instead a
ball bearing. •
Tri-Ad Lock – A locking mechanism exclusively licensed to
Cold Steel. It is a form of lockback which incorporates a thick steel stop pin between the front of the latch and the back of the tang to transfer force from the blade into the handle. •
PickLock – A round post on the back base of the blade locks into a hole in a spring tab in the handle. To close, manually lift (pick) the spring tab (lock) off the blade post with your fingers, or in "Italian Style Stilettos" swivel the bolster (hand guard) clockwise to lift the spring tab off the blade post. Another prominent feature of many folding knives is the opening mechanism. Traditional pocket knives and
Swiss Army knives commonly employ the nail nick, while modern folding knives more often use a stud, hole, disk, or
flipper located on the blade, all of which have the benefit of allowing the user to open the knife with one hand. The "wave" feature is another prominent design, which uses a part of the blade that protrudes outward to catch on one's pocket as it is drawn, thus opening the blade; this was patented by
Ernest Emerson and is not only used on many of the Emerson knives, but also on knives produced by several other manufacturers, notably
Spyderco and
Cold Steel.
Automatic or
switchblade knives open using the stored energy from a spring that is released when the user presses a button or lever or other
actuator built into the handle of the knife. Automatic knives are severely restricted by law in the UK and most American states. Increasingly common are
assisted opening knives which use springs to propel the blade once the user has moved it past a certain angle. These differ from automatic or switchblade knives in that the blade is not released by means of a button or catch on the handle; rather, the blade itself is the actuator. Most assisted openers use flippers as their opening mechanism. Assisted opening knives can be as fast or faster than automatic knives to deploy.
Common locking mechanisms In the
lock back, as in many folding knives, a stop pin acting on the top (or behind) the blade prevents it from rotating clockwise. A hook on the tang of the blade engages with a hook on the rocker bar which prevents the blade from rotating counter-clockwise. The rocker bar is held in position by a torsion bar. To release the knife the rocker bar is pushed downwards as indicated and pivots around the rocker pin, lifting the hook and freeing the blade. When negative pressure (pushing down on the spine) is applied to the blade all the stress is transferred from the hook on the blade's tang to the hook on the rocker bar and thence to the small rocker pin. Excessive stress can shear one or both of these hooks rendering the knife effectively useless. Knife company Cold Steel uses a variant of the lock back called the
Tri-Ad Lock which introduces a pin in front of the rocker bar to relieve stress on the rocker pin, has an elongated hole around the rocker pin to allow the mechanism to wear over time without losing strength and angles the hooks so that the faces no longer meet vertically. The bolt in the
bolt lock is a rectangle of metal that is constrained to slide only back and forward. When the knife is open a spring biases the bolt to the forward position where it rests above the tang of the blade preventing the blade from closing. Small knobs extend through the handle of the knife on both sides allowing the user to slide the bolt backward freeing the knife to close. The
Axis Lock used by knife maker Benchmade is functionally identical to the bolt lock except that it uses a cylinder rather than a rectangle to trap the blade. •
Plastic handles are more easily cared for than wooden handles, but can be slippery and become brittle over time. •
Injection molded handles made from higher grade plastics are composed of
polyphthalamide, and when marketed under trademarked names such as
Zytel or
Grivory, are reinforced with
Kevlar or
fiberglass. These are often used by major knife manufacturers. •
Rubber handles such as
Kraton or Resiprene-C are generally preferred over plastic due to their durable and cushioning nature. •
Micarta is a popular handle material on
user knives due to its toughness and stability. Micarta is nearly impervious to water, is
grippy when wet, and is an excellent insulator. Micarta has come to refer to any fibrous material cast in resin. There are many varieties of micarta available. One very popular version is a fiberglass impregnated resin called G-10. •
Leather handles are seen on some hunting and military knives, notably the
KA-BAR. Leather handles are typically produced by stacking leather washers, or less commonly, as a sleeve surrounding another handle material. Russian manufacturers often use
birchbark in the same manner. • Skeleton handles refers to the practice of using the tang itself as the handle, usually with sections of material removed to reduce weight. Skeleton handled knives are often wrapped with
parachute cord or other wrapping materials to enhance grip. •
Stainless steel and
aluminum handles are durable and sanitary, but can be slippery. To counter this, premium knife makers make handles with ridges, bumps, or indentations to provide extra grip. Another problem with knives that have metal handles is that, since metal is an excellent heat-conductor, these knives can be very uncomfortable, and even painful or dangerous, when handled without gloves or other protective
handwear in (very) cold climates. , Indonesia) More exotic materials usually only seen on art or ceremonial knives include: Stone, bone, mammoth tooth, mammoth ivory, oosik (walrus penis bone), walrus tusk, antler (often called stag in a knife context), sheep horn, buffalo horn, teeth, and mop (mother of pearl or "pearl"). Many materials have been employed in knife handles. Handles may be adapted to accommodate the needs of people with disabilities. For example, knife handles may be made thicker or with more cushioning for people with
arthritis in their hands. A non-slip handle accommodates people with
palmar hyperhidrosis. ==Types==