A stent (20) is made from a wire by winding the wire on a mandrel (22), heating to form a coiled spring, and reversing the winding direction of the coiled spring to form the reversed coiled spring stent (20). The stent so formed may be reheated over a special mandrel so as to partly relax the outer portion of some or all of the stent coils. The stent may be made up of two or more sections, with adjoining sections wound in opposite senses. Such a stent may be deployed by winding the stent onto a catheter, immobilizing the two ends of the wire and one or more intermediate points, bringing the stent to the location where it is to be deployed, and releasing first the intermediate point or points and then the end points. The release of the wire may be accomplished by heating the thread immobilizing the wire so that the thread breaks and releases the wire.

A process of producing a steel wire for automatic coiling, said process comprising the steps of: providing Ni plating having a thickness of from 1 to 5 µm to a steel wire containing 0.15% by weight or less of carbon, 1.00% by weight or less of sulfur, 2.00% by weight or less of manganese, 6.50% by weight or more and less than 14% by weight of nickel, and from 17.00 to 20.00% by weight of cromium; coating thereon a synthetic resin containing a halogen; drawing said steel wire to a reduction of cross-sectional area of at least 60%, with adjusting the surface roughness thereof to the range of from 0.8 to 12 s. A steel wire for automatic coiling comprising a steel wire containing 0.15% by weight or less of carbon, 1.00% by weight or less of sulfur, 2.00% by weight or less of manganese, 6.50% by weight or more and less than 14% by weight of nickel, and from 17.00 to 20.00% by weight of cromium, having thereon Ni plating having a thickness of from 0.3 to 1.7 µm and having further coated thereon a synthetic resin containing a halogen, the tensile strength of the wire being at least 160 kgf/mm² and the surface roughness thereof being from 0.8 to 12 s.

The present invention relates to a spring producing apparatus which is constituted such that a drive roller (2) is connected to a controlled speed motor (13) with a clutch brake via a suitable transmission mechanism while a bending die (7) and a pitch tool (10) are connected to adjusting actuators (16) and (22) by way of cam means (17) and (23), respectively, and a cutter (11) is connected to a cutting actuator, whereby operations of the motor (13) and the actuators (16) and (22) are set and controlled suitably by a controller. The present invention further relates to a spring producing apparatus which comprises a chuck (100) connected to a reversible motor with a clutch brake by way of a transmission mechanism, a metal core (101) fittably and removably mounted on the chuck (100), a pitch tool/guide member (117) mounted on a linear guide (110) which is moved in a parallel relationship to the metal core on the chuck, a wire stock (103) which is fed through a nozzle (120) of the pitch tool/guide member (117) being fitted into and arrested by the chuck (100) whereafter the wire stock (103) is wrapped into coils around the metal core (101), an actuator (126) disposed on the linear guide (110) for movement together with the pitch tool/guide member (117) so as to be pushed against or pulled by the guide (117) to apply a predetermined pitch to the coils, and a cutter (152) which is moved up and down by operation of a cutting actuator (153) after releasing of the push or pull at the actuator (126).

A coil of taper wire for forming coil springs, formed by winding substantially in concentric loops a quench-hardened and tempered taper wire having a successive arrangement of taper wire segments each consisting of a thick section (4), two thin sections (5) and two taper sections (6) connecting the thin sections to the opposite ends of the thick section, respectively. The taper wire is subjected to a preforming action immediately before being wound in loops on a winding drum, to form plastic bends in the thick sections and plastic bends of a radius (R₂) of curvature greater than (R₁) that of the plastic bends in the thick sections so that the taper wire is wound substantially uniform, concentric circular loops on a winding drum. When the taper wire is unwound from the coil and is subjected to a straightening process of a fixed straightening arrangement of a series of straightener rollers before being coiled in taper wire coil springs on a coil spring forming mill, the thick sections undergo a straightening action greater than that acts on the thin sections, so that the taper wire unwound from the coil of taper wire is straightened in a substantially straight taper wire and thereby the taper wire is coiled in taper wire coil springs having correct size and uniform shape.

Die Federwindemaschine ist mit einem am Maschinenständer (11) beweglich gelagerten und kurvengesteuerten Steigungswerkzeug (3) versehen. Dessen Bewegung wird von einer um eine Achse drehbaren Steuerkurvenscheibe (38, 39) mit einem Auflauf- und Ablaufabschnitt über einen Hebelmechanismus (9 bis 19,24 bis 27) in einer einstellbaren Phasenlage zum Maschinentakt erzeugt. Um die Einstellver- lustzeiten der Maschine möglichst klein zu halten ist vorgesehen, dass die Achse durch die Achsen von zwei koachsialen Halbwellen (40, 47 bzw. 41,47') gebildet wird. Weiter wird die Funktion der Steuerkurvenscheibe auf ein Kurvenscheibenpaar (38, 39) mit einer ersten und einer zweiten Kurvenscheibe (38 bzw. 39) aufgeteilt, wobei auf der ersten Halbwelle (40, 47) die erste Kurvenscheibe (38), welche den Auflaufabschnitt aufweist, und auf der zweiten Halbwelle (41,47') die zweite Kurvenscheibe (39) mitdrehend aufgesetzt ist, welche den Ablaufabschnitt aufweist. Der Hebelmechanismus weist ein schwenkbar gelagertes Hebelorgan (15 bis 19, 24 bis 27) auf, das mit zwei Armen (24,25) versehen ist, von denen der eine (24) die erste Kurvenscheibe (38) und der andere (25) die andere Kurvenscheibe (39) abgreift, wobei der Hebelmechanismus in Wirkverbindung mit dem Steigungswerkzeug (3) ist und dessen Bewegung erzwingt. Die relative Drehlage zwischen den Kurvenscheiben (38, 39) und der Achse ist je durch einen Verstellmechanismus (40, 43, 44 bis 50,52 bzw. 41, 43', 44' bis 50', 52') veränderbar wozu auf jeden Verstellmechanismus ein im Maschinenständer entlang einer Linie verstellbares Einstellorgan (52, 52') wirkt, um die Phasenlage der Kurvenscheibe (38, 39) gegenüber dem Maschinentakt zu verändern.