Variable friction hinge

What is claimed: 1. A hinge assembly having variable friction torque, the hinge assembly comprising: an elongated element having an elongated element surface extending generally along a longitudinal axis; at least one torque element positioned along the elongated element surface for rotation with respect to the longitudinal axis, the at least one torque element having end portions, a torque element surface extending between the end portions, a first condition in which at least a portion of the torque element surface is in friction contact with the elongated element surface and the torque element is in compressive engagement with the elongated element for friction resistance to rotation, and a second condition in which the compressive engagement with the elongated element and the friction resistance to rotation is reduced or eliminated; and at least one actuator between the end portions of the torque element and coupled for movement with respect to the at least one torque element, the at least one actuator being configured to change the friction torque generated between the elongated element and the at least one torque element, the at least one actuator having an actuator surface positioned to contact at least one of the end portions of the at least one torque element and to change the distance between the end portions of the at least one torque element and thereby move the at least one torque element toward the first condition or the second condition, thus changing frictional resistance to rotation of the at least one torque element with respect to the elongated element, wherein the at least one actuator comprises a cam positioned for rotation with respect to the at least one torque element, the actuator surface being a cam surface contacting at least one of the end portions of the at least one torque element, wherein rotation of the cam with respect to the at least one torque element changes the distance between the end portions of the at least one torque element, thus changing frictional resistance to rotation of the at least one torque element with respect to the elongated element. 2. The hinge assembly of claim 1 , wherein the elongated element comprises a shaft extending along the longitudinal axis and the torque element surface of the at least one torque element faces an outer elongated element surface of the shaft. 3. The hinge assembly of claim 1 comprising a plurality of torque elements, wherein the cam surface of the cam contacts at least one of the end portions of each of the torque elements, wherein rotation of the cam with respect to the torque elements changes the distance between the end portions of each of the torque elements, thus changing frictional resistance to rotation of each of the torque elements with respect to the elongated element and providing simultaneous relief of frictional resistance. 4. The hinge assembly of claim 1 comprising a plurality of torque elements, wherein the cam surface of the cam contacts at least one of the end portions of fewer than all of the torque elements, wherein rotation of the cam with respect to the torque elements changes the distance between the end portions of fewer than all of the torque elements, thus changing frictional resistance to rotation of fewer than all of the torque elements with respect to the elongated element and providing sequential relief of frictional resistance. 5. The hinge assembly of claim 1 , wherein the cam is configured to rotate in response to the rotational position of the at least one torque element with respect to the elongated element to adjust the frictional resistance to rotation of the at least one torque element with respect to the elongated element based on the rotational position in a span of rotational movement. 6. The hinge assembly of claim 1 , wherein the cam is configured to rotate in response to the rotational direction of movement of the at least one torque element with respect to the elongated element to adjust the frictional resistance to rotation of the at least one torque element with respect to the elongated element based on the rotational direction of movement. 7. The hinge assembly of claim 1 , wherein the cam is positioned for rotation about an axis substantially parallel to the longitudinal axis of the elongated element. 8. The hinge assembly of claim 1 , wherein the cam is positioned for rotation about an axis substantially perpendicular to the longitudinal axis of the elongated element. 9. The hinge assembly of claim 1 , wherein the at least one torque element comprises a clip. 10. The hinge assembly of claim 1 , wherein the at least one torque element comprises a band. 11. A hinged system assembly having variable friction torque, the hinged system comprising components positioned for rotational movement with respect to one another and the hinge assembly of claim 1 coupled to the components, wherein the at least one actuator is configured to change the friction torque generated between the components, thus changing frictional resistance to rotation of the components with respect to one another. 12. The hinge assembly of claim 1 , wherein in the second condition, the portion of the torque element surface in friction contact with the elongated element surface is reduced or eliminated. 13. A method for facilitating variable friction resistance in a hinge, the method comprising: compressively engaging a generally cylindrical surface of at least one torque element with a generally cylindrical surface of an elongated element; positioning an actuator between end portions of the at least one torque element to selectively change the relative position of the end portions to change the friction resistance generated by the at least one torque element, thus reducing compressive engagement between the cylindrical surface of the at least one torque element and the cylindrical surface of the elongated element; wherein the actuator comprises a cam positioned for rotation with respect to the at least one torque element, the actuator having a cam surface contacting at least one of the end portions of the at least one torque element, wherein the positioning step includes rotation of the cam with respect to the at least one torque element and changing the distance between the end portions of the at least one torque element, thus changing frictional resistance to rotation of the at least one torque element with respect to the elongated element. 14. A method for varying friction resistance between components positioned for rotational movement with respect to one another, the method comprising: rotating the components with respect to one another away from a first position toward a second position causing at least one torque element to rotate with respect to the longitudinal axis of an elongated element in a first condition in which at least a portion of a torque element surface of the at least one torque element is in friction contact with an elongated element surface of the elongated element; changing the friction torque generated between the elongated element and the at least one torque element at the second position by changing the distance between end portions of the at least one torque element with an actuator positioned between the end portions and moving the at least one torque element from the first condition toward a second condition in which a compressive force between the torque element surface and the elongated element surface is reduced or eliminated, thus changing frictional resistance to rotation of the at least one torque element with respect to the elongated element; and rotating the components with respect to one another away from the second