This shedding mechanism includes a housing and a movable hook which can be retained by a selection device including at least one electromagnet (100) immobilized in the housing and which includes a ferromagnetic core (102) comprising first and second pole faces (S122, S124). The electromagnet (100) also includes a non-magnetic portion (104, 108) and a retaining lever configured to retain the movable hook. The retaining lever is pivotally mounted about an oscillation axis (A144) and includes a ferromagnetic armature (202) that interacts magnetically with the first and second pole faces. The non-magnetic portion of the electromagnet includes a surface (S144) for guiding the pivoting of the retaining lever. This guide surface cooperates with the retaining lever in a direction radial to the oscillation axis (A144) between a remote position and a contact position. The guide surface (S144) is cylindrical with a circular base, centered on the oscillation axis.

This shedding mechanism includes a housing and a movable hook which can be retained by a selection device including at least one electromagnet (100) immobilized in the housing and which includes a ferromagnetic core (102) comprising first and second pole faces (S122, S124). The electromagnet (100) also includes a non-magnetic portion (104, 108) and a retaining lever configured to retain the movable hook. The retaining lever is pivotally mounted about an oscillation axis (A144) and includes a ferromagnetic armature (202) that interacts magnetically with the first and second pole faces. The non-magnetic portion of the electromagnet includes a surface (S144) for guiding the pivoting of the retaining lever. This guide surface cooperates with the retaining lever in a direction radial to the oscillation axis (A144) between a remote position and a contact position. The guide surface (S144) is cylindrical with a circular base, centered on the oscillation axis.

A weaving loom produces a fabric (F), with warp yarns and in-woven weft yarns. The weaving loom includes a warp delivery unit, heddles to form a shed, a shedding mechanism for moving each heddle vertically along a vertical path, a weft insertion means for inserting each weft yarn in a shed and for releasing each weft yarn at a given location along a weft axis, and a weft delivery means for delivering each weft yarn to the weft insertion means. The weaving loom also includes a programmable clamping means for picking up a first end of each weft yarn and for releasing each weft yarn at any predetermined position along the weft axis, and a programmable mechanism including actuators for semi-closing the shed around the inserted weft yarn at any predetermined position along the weft axis.

A selvage yarn shedding apparatus of a loom including two support bodies each having carrier rods configured to support a heddle into which a selvage yarn is inserted and a slide guide having both end portions to which the carrier rods are attached; a drive motor configured to drive in forward-reverse rotations; a support frame including a guide member; and a motion conversion mechanism configured to convert rotation of an output shaft of a drive motor into reciprocating motion in upper-lower direction of each support body. Each of the support bodies includes a connecting part including an extension portion provided above the carrier rod and extending from the slide guide in a longitudinal direction of the carrier rod toward a side where the heddle exists, where the connecting part is configured to connect the slide guide and the motion conversion mechanism each other at the extension portion.

A shedding machine includes an eccentric system rotatable about a main axis; a lever; and a transmission rod, coupled to the eccentric system and pivotally to the lever about the eccentric axis and connecting rod axis spaced apart by a connecting rod center distance, the main axis and the eccentric axis being spaced apart by an eccentric center distance. To facilitate the adjustment of the stroke of a heald frame operated by the machine, which includes an adjustment system, allowing an adjustment configuration where the eccentric distance or connecting rod distance is adjustable, and a locked configuration where these distances are fixed. The machine also includes a locking system, which allows lever locking and lever release configurations.

A machine and method are presented for continuously forming a woven composite with controllable internal fabric geometry. The machine may include one or more spools for dispensing one or more warp filaments, a roller assembly configured to receive a composite weave, a warp rack having a plurality of warp heads for engaging the warp filaments and vertically adjusting position to dynamically create a weave pattern in response to the insertion of one or more weft filaments by a weft inserter stack.

A bursitis treatment device (100; 200) for treatment of inflammation of a bursa (150; 502) in a patient's joint includes: a rinsing aid; a reservoir (101; 201) for holding the rinsing aid in fluid, freezing fluid or gaseous state; a supply line (103; 204, 208) for transporting the rinsing aid; a heat exchanger (104; 203) for controlling the temperature of the rinsing aid—such that the temperature of the rinsing aid enables to destroy cells causing the inflammation; an access device (209) for injecting the rinsing aid into the bursa (150; 205); and a drain (105; 210) for removing the rinsing aid from the bursa (150; 205) for elimination.

A bursitis treatment device (100; 200) for treatment of inflammation of a bursa (150; 502) in a patient's joint includes: a rinsing aid; a reservoir (101; 201) for holding the rinsing aid in fluid, freezing fluid or gaseous state; a supply line (103; 204, 208) for transporting the rinsing aid; a heat exchanger (104; 203) for controlling the temperature of the rinsing aid—such that the temperature of the rinsing aid enables to destroy cells causing the inflammation; an access device (209) for injecting the rinsing aid into the bursa (150; 205); and a drain (105; 210) for removing the rinsing aid from the bursa (150; 205) for elimination.

The invention relates to an actuator assembly 20 for a textile machine 22, wherein: the actuator assembly comprises a plurality n of spools 24 distributed along depth d; the actuator assembly comprises a plurality n+1 of magnetic plates 26 distributed along depth d; the magnetic plates and the spools are alternated along depth d such that each spool is received between two adjacent magnetic plates; each magnetic plate comprises an upper permanent magnet 28 and a lower permanent magnet 30 having opposed orientation; the upper permanent magnets of all the magnetic plates have the same orientation; the lower permanent magnets of all the magnetic plates have the same orientation; each spool is movable along height h between an upper position and a lower position and vice versa.

The invention relates to an actuator assembly 20 for a textile machine 22, wherein: the actuator assembly comprises a plurality n of spools 24 distributed along depth d; the actuator assembly comprises a plurality n+1 of magnetic plates 26 distributed along depth d; the magnetic plates and the spools are alternated along depth d such that each spool is received between two adjacent magnetic plates; each magnetic plate comprises an upper permanent magnet 28 and a lower permanent magnet 30 having opposed orientation; the upper permanent magnets of all the magnetic plates have the same orientation; the lower permanent magnets of all the magnetic plates have the same orientation; each spool is movable along height h between an upper position and a lower position and vice versa.