Magnetic device for gripping and clamping workpieces

The invention claimed is: 1. A device for gripping and withholding workpieces made of ferromagnetic material by means of at least one permanent magnet, the device comprising: a supporting casing ( 2 ); a magnet-holder member ( 4 ), carrying a main permanent magnet (M) and slidably mounted in the supporting casing ( 2 ) between an advanced position, corresponding to an operative position of the main magnet (M), and a retracted position, corresponding to an inoperative position of the main magnet (M); actuator means (E, A 1 , A 2 , B) carried at least in part by the casing ( 2 ), for governing a displacement of the magnet-holder member ( 4 ) between the advanced position and the retracted position, the actuator means comprising: a first shape-memory actuator elements (A 1 , A 2 ) for governing a displacement of the magnet-holder member ( 4 ) from its advanced position to its retracted position; and second shape-memory actuator elements (B) for governing a displacement of the magnet-holder member ( 4 ) from its retracted position to its advanced position, the shape-memory actuator elements (A 1 , A 2 , B), which are constituted by a shape-memory metal alloy and are designed to undergo a phase transition when their temperature exceeds a predetermined threshold value; and means (E) for supplying an electric current through the shape-memory actuator elements (A 1 , A 2 , B) so as to bring their temperature above the threshold value, wherein the magnet-holder member ( 4 ) bears the permanent magnet (M) at a front end and moreover bears at a distal end an auxiliary magnet (m), which generates a magnetic field of lower intensity than that of the main magnet (M), the auxiliary magnet (m) adhering to a metal wall ( 2 c ) of the casing ( 2 ) when the magnet-holder member ( 4 ) is in its retracted position so as to keep the magnet-holder member ( 4 ) stably in the retracted position even after an interruption of the passage of electric current through the first shape-memory actuator elements (A 1 , A 2 ), which are used for displacing the magnet-holder member ( 4 ) towards the retracted position, wherein the first actuator elements (A 1 , A 2 ) are selectively adapted to positionally displace the magnet-holder member ( 4 ) toward the wall ( 2 c ) along an axis ( 3 a ) equal to the entire length necessary to pass from the operative position of the main magnet (M) to the position in which the auxiliary magnet (m) is in contact with the wall ( 2 c ) of the casing ( 2 ), whilst the second actuator elements (B) are selectively adapted to positionally displace the magnet-holder member ( 4 ) toward the advanced position along the axis ( 3 e ) equal just to a portion of the aforesaid length, the remaining portion of displacement forwards being obtained via the magnetic attraction between the main magnet (M) and the workpiece (L) to be clamped, wherein slidably mounted within the casing ( 2 ) is an auxiliary member ( 6 ) and wherein the first shape-memory actuator elements (A 1 , A 2 ) that selectively displace the magnet-holder member ( 4 ) toward the wall ( 2 c ) comprise a first set of one or more wires (A 1 ) made of shape-memory alloy operatively connected between the magnet-holder member ( 4 ) and the auxiliary sliding member ( 6 ), and a second set of wires (A 2 ) made of shape-memory alloy operatively connected between the auxiliary sliding member ( 6 ) and the rear side of the casing ( 2 ) in such a way that the displacement of the magnet-holder member ( 4 ) toward the wall ( 2 c ) is obtained upon both the movement of the magnet-holder member ( 4 ) with respect to the auxiliary sliding member ( 6 ), caused by shortening of the shape-memory wires (A 1 ) of the first set, and the movement of the auxiliary sliding member ( 6 ) with respect to the casing ( 2 ), caused by shortening of the shape-memory wires (A 2 ) of the second set. 2. The device according to claim 1 , wherein the second shape-memory actuator elements that selectively displace the magnet-holder member ( 4 ) toward the advanced position comprise a third set of one or more wires (B) made of shape-memory alloy operatively connected between the front side of the casing ( 2 ) and the magnet-holder member ( 4 ). 3. The device according to claim 2 , wherein the shape-memory wires (B) of the third set extend through axial cavities ( 4 d ) of the magnet-holder member ( 4 ) between the front side of the casing ( 2 ) and the rear end of the body of the magnet-holder member ( 4 ). 4. The device according to claim 1 , wherein the wires made of shape-memory alloy (A 1 ) of the first set and the shape-memory wires (A 2 ) of the second set extend through axial channels ( 4 c , 6 c , 6 d ) made through a body of the magnet-holder member ( 4 ) and through a body of the auxiliary sliding member ( 6 ) and are at least partially set on top of one another in the axial direction. 5. The device according to claim 4 , wherein the auxiliary sliding member ( 6 ) has a main portion ( 6 a ) of a first diameter, mounted so that it can slide within the casing ( 2 ) at the rear to the magnet-holder member ( 4 ), and a central axial stem ( 6 b ) of second diameter mounted so that it can slide within a cylindrical axial cavity ( 4 b ) of the magnet-holder member ( 4 ), the second diameter smaller than the first diameter, the channels ( 6 d ) within which the aforesaid second shape-memory wires (A 2 ) extend being made through the main portion ( 6 a ) and through the stem ( 6 b ) of the auxiliary sliding member ( 6 ) in such a way that the second shape-memory wires (A 2 ) extend between the front end of the stem ( 6 b ) of the auxiliary sliding member ( 6 ) and the rear side of the casing ( 2 ), whilst the shape-memory wires (A 1 ) of the first set extend both through channels ( 4 c ) made in the body of the magnet-holder member ( 4 ) in the part surrounding the cavity ( 4 b ) and through axial channels ( 6 c ) made in the main portion ( 6 a ) of the auxiliary sliding member ( 6 ), externally to the channels ( 6 d ) that contain the second shape-memory wires (A 2 ) in such a way that the shape-memory wires (A 1 ) of the first set extend between the front end of the magnet-holder member ( 4 ) and the rear end of the auxiliary sliding member ( 6 ).