Abstract: A solid particulate capturing device comprises a first plate (2) having at least one inlet section (6) for an exhaust gas flow, a second plate (3), parallel to the first (2), having at least one outlet section (7) for the exhaust gas flow. The first (2) and the second plate (3) are axially spaced apart and form, with an annular lateral wall (4), interposed between the first (2) and the second plate (3), an entrapment chamber (5) for solid particulate conveyed in suspension in the exhaust gas flow produced by a battery. The outlet section (7) present on the second plate (3) is axially out of alignment with the inlet section (6) present on the first plate (2), in such a way that the inlet section (6) faces a solid portion (8) of the second plate (3) which acts as an obstructing surface for the solid particulate.

Abstract: A solid particulate capturing device comprises a first plate (2) having at least one inlet section (6) for an exhaust gas flow, a second plate (3), parallel to the first (2), having at least one outlet section (7) for the exhaust gas flow. The first (2) and the second plate (3) are axially spaced apart and form, with an annular lateral wall (4), interposed between the first (2) and the second plate (3), an entrapment chamber (5) for solid particulate conveyed in suspension in the exhaust gas flow produced by a battery. The outlet section (7) present on the second plate (3) is axially out of alignment with the inlet section (6) present on the first plate (2), in such a way that the inlet section (6) faces a solid portion (8) of the second plate (3) which acts as an obstructing surface for the solid particulate.

Abstract: Described is a safety disc comprising a foil element (3) having a thickness (s) of between 15 ?m and 1 mm and at least one non-through cut (2) having a width (L) less than or equal to 200 ?m, such that the ratio between width (L) and depth (H) is less than or equal to 2 and that the angle of penetration (a) of the cut is less than 90°.

Abstract: A method for production of safety/rupture discs (1) comprises the steps providing a foil element (1a), selecting a wavelength for a laser beam of a pulse laser within a range of between 800 nanometers and 1800 nanometers, selecting a pulse repetition rate for the laser beam within a range of between 15 KHz and 800 KHz, selecting a pulse duration for the laser beam less than 10 nanosecond and ablating at least one non-through cut (2) in the foil element by directly applying said laser beam to the foil element to remove material from the foil element (1a) thereby obtaining a safety/rupture disc.

Abstract: A method for production of safety/rupture discs comprises the steps providing a foil element, selecting a wavelength for a laser beam of a pulse laser within a range of between 800 nanometers and 1800 nanometers, selecting a pulse repetition rate for the laser beam within a range of between 15 KHz and 800 KHz, selecting a pulse duration for the laser beam less than 10 nanosecond and ablating at least one non-through cut in the foil element by directly applying said laser beam to the foil element to remove material from the foil element thereby obtaining a safety/rupture disc.

Abstract: A method for production of safety/rupture discs comprises the steps providing a foil element, selecting a wavelength for a laser beam of a pulse laser within a range of between 800 nanometers and 1800 nanometers, selecting a pulse repetition rate for the laser beam within a range of between 15 KHz and 800 KHz, selecting a pulse duration for the laser beam less than 10 nanosecond and ablating at least one non-through cut in the foil element by directly applying said laser beam to the foil element to remove material from the foil element thereby obtaining a safety/rupture disc.

Abstract: A method for production of safety/rupture devices having pre-calculated breaking threshold comprises the steps of providing a plate (2) having at least one metallic surface (2a); making at least one cut (5) in said surface (2a) of said plate (2) to define a frangible line of pre-established rupture. The step of making at least one cut (5) is obtained by application of a laser beam (8) directly onto said metallic surface (2a).