In some embodiments, an archery bow riser comprises a body defining a first end, a second end and a grip portion. The body defines a shooting axis and comprises a first portion and a second portion. The first portion comprises a metal and the second portion comprises carbon fibers. The first portion extends to a first side of the shooting axis and to a second side of the shooting axis, and the second portion extends to the first side of the shooting axis and to the second side of the shooting axis.

An archery bow comprises a riser, two limbs with a bow string coupled between them, and an arrow rest comprising: a body coupled with the riser via a mount; a first arm having a rotatable shaft extending from the body; a tab extending radially from the rotatable shaft; a second arm having a second rotatable shaft extending from the body and coupled by gearing to the rotatable shaft; a second tab extending radially from the second rotatable shaft; and a drive mechanism. The tab has a recess. The second tab has a second recess. In an encapturing configuration, the recesses form an aperture to encapture an arrow shaft when portions of the tabs are substantially in plane. In a discharge configuration the aperture releases the arrow shaft when the portions are substantially parallel. The drive mechanism rotates the first and second arms from the encapturing configuration to the discharge configuration.

A projectile launcher includes a frame having a vertical grip and a forearm brace configured to stabilize the projectile launcher using a user's arm. The projectile launcher includes a drawstring hub rotatably mounted to the frame and rotatable in a first direction and a second direction. Movement of a drawstring away from the drawstring hub corresponds with rotation of the drawstring hub in the first direction and movement of the drawstring toward the drawstring hub corresponds with rotation of the drawstring hub in the second direction. The projectile launcher includes at least one flexible limb attached to at least one power cable. A power cable section of the drawstring hub, where the power cable is connected, has a let-off portion. The let-off portion has a first section having a first diameter and a second section having a second diameter and the first diameter is greater than the second diameter.

A projectile launching device includes self-timing without cam lean. The projectile launching device preferably includes a rail, a riser, two energy storing components, (such as two limbs), two cams, a launch string, and at least two cables. The ends of the launch string are attached to the two cams. Opposing ends of first and second cables are coupled to the first and second cams. A mid-segment of the first and second cables are slidably engaged with the first and second cable pulleys, respectively. The two cams are preferably built as mirror images of each other at a centerline of the rail. The two cams include a launch string track, having identical, but mirrored, upper and lower cable tracks.

A protection device of a crossbow includes a protection coat that is mounted to the limb. The flexibility of the protection coat greater than the flexibility of the limb so that the protection coat is deformed with the limb when the limb is deformed. The protection coat absorbs vibration from the limb when the limb bounces back so as to protect the limb from being broken by reducing the vibration amplitude.

A method of constructing a crossbow may include the steps of: supporting the riser to the main beam; supporting a pair of bow limbs to the ends of the riser; separating the bow limbs such that a minimum distance between them is not greater than about 5 inches; supporting the bowstring to the bow limbs; and providing at least a portion of the opening in the riser to be as wide as a user's foot and to extend between the bow limb.

The present disclosure provides for a cam assembly, the cam assembly comprising a shoot cam and a charge cam. The shoot cam is configured to be operatively coupled to the charge cam. The cam assembly is configured to store a potential energy in response to a draw of a drawstring.

In some embodiments, an archery bow comprises a limb supported by a riser and an axle supported by the limb. A plurality of bearings are supported by the axle, which comprise a first dynamic bearing and a second dynamic bearing. A rotatable member is supported by the plurality of bearings. The first dynamic bearing is shaped differently from the second dynamic bearing. In some embodiments, the axle comprises a non-contacting length portion comprising less than 15% of the axle length.

Described is an archery device for transmitting power aimed at transmitting power from at least one limb to at least one arrow using at least one cam which is operatively connected to two or more flexible, substantially inextensible elements, designed to withstand tensile stress (cables and strings or tracts thereof), simultaneously operating at least one string tract and several cable tracts, the latter, in different directions to each other, wherein the net radial moment is determined by the combination of tensions and directions of the elements connected to it. This increases the design freedom when positioning the cam and reduces the friction linked to its rotation against a support, if necessary, making it possible to do without a support, thereby eliminating friction and improving efficiency.

A bow enabling high hit rate is provided. A bow 1 includes: a bow body 10 having a long hole 121; a grip 80 having a connection pin 81 which is inserted into the long hole 121 and movable in a longitudinal direction of the long hole 121, the grip 80 being connected with the bow body 10 in a state that the connection pin 81 is inserted into the long hole 121; and an elastic member 90 that connects the bow body 10 and the connection pin 81, wherein the elastic member 90 is elastically deformed to apply an elastic force to the bow body 10 and the connection pin 81 when the bow body 10 is moved with respect to the grip 80 by a drawing operation and the connection pin 81 is relatively moved in the longitudinal direction of the long hole 121.