The present invention concerns an apparatus for irradiating goods with X-rays, comprising a first source of X-rays configured for emitting X-rays along a first irradiation volume centered on a longitudinal axis (X), and a conveyor configured for driving goods such as to expose a first portion of the goods through the first irradiation volume, wherein, the conveyor is configured for driving the target products through the irradiation volume along a vertical axis (Z).

The present invention concerns an apparatus for irradiating goods with X-rays, comprising a first source of X-rays configured for emitting X-rays along a first irradiation volume centered on a longitudinal axis (X), and a conveyor configured for driving goods such as to expose a first portion of the goods through the first irradiation volume, wherein, the conveyor is configured for driving the target products through the irradiation volume along a vertical axis (Z).

Methods for pasteurizing and/or sterilizing particulate goods (1), containing the following steps: a) producing an electron beam (5), b) pasteurizing and/or sterilizing the goods (1) by the electron beam (5) in a treatment zone (3), wherein the electrons of the electron beam (5) have an energy that lies in the range of 80 keV to 300 keV, preferably from 140 keV to 280 keV, and more preferably from 180 keV to 260 keV, the goods (1) are exposed to the electron beam (5) for a treatment time which lies in the range from 5 ms to 25 ms, and the electron beam (5) has a mean electron current density in the treatment zone (3) which lies in the range of 10.sup.15 s.sup.−1.Math.cm.sup.−2 to 2.77.Math.10.sup.15 s.sup.−1.Math.cm.sup.−2.

Methods for pasteurizing and/or sterilizing particulate goods (1), containing the following steps: a) producing an electron beam (5), b) pasteurizing and/or sterilizing the goods (1) by the electron beam (5) in a treatment zone (3), wherein the electrons of the electron beam (5) have an energy that lies in the range of 80 keV to 300 keV, preferably from 140 keV to 280 keV, and more preferably from 180 keV to 260 keV, the goods (1) are exposed to the electron beam (5) for a treatment time which lies in the range from 5 ms to 25 ms, and the electron beam (5) has a mean electron current density in the treatment zone (3) which lies in the range of 10.sup.15 s.sup.−1.Math.cm.sup.−2 to 2.77.Math.10.sup.15 s.sup.−1.Math.cm.sup.−2.

A surgical instrument for use with a robotic system that has a control unit and a shaft portion that includes an electrically conductive elongated member that is attached to a portion of the robotic system. The elongated member is configured to transmit control motions from the robotic system to an end effector.

A surgical instrument for use with a robotic system that has a control unit and a shaft portion that includes an electrically conductive elongated member that is attached to a portion of the robotic system. The elongated member is configured to transmit control motions from the robotic system to an end effector.

A devices (10) and method for pasteurizing and/or sterilizing particulate material. The device contain at least one electron source (20) for generating an electron beam and a treatment zone (19) in which the material is pasteurized and/or sterilized by the electron beam. The device (10) comprises a vibration surface (11) which vibrates to convey and individualize the material. The first vibration surface (11) has a plurality of grooves (12) into which the material is conveyed and individualized. The device (10) has a material channel (21) in which the material is pasteurized and/or sterilized by the electron beam in the region of the treatment zone (19). The device (10) has at least one auxiliary channel (22) through which a fluid flows, between the electron source (20) and the material channel (21), and is separated from the material channel (21). A cartridge (24) for pasteurizing and/or sterilizing particulate material is also disclosed.

A devices (10) and method for pasteurizing and/or sterilizing particulate material. The device contain at least one electron source (20) for generating an electron beam and a treatment zone (19) in which the material is pasteurized and/or sterilized by the electron beam. The device (10) comprises a vibration surface (11) which vibrates to convey and individualize the material. The first vibration surface (11) has a plurality of grooves (12) into which the material is conveyed and individualized. The device (10) has a material channel (21) in which the material is pasteurized and/or sterilized by the electron beam in the region of the treatment zone (19). The device (10) has at least one auxiliary channel (22) through which a fluid flows, between the electron source (20) and the material channel (21), and is separated from the material channel (21). A cartridge (24) for pasteurizing and/or sterilizing particulate material is also disclosed.

A disinfecting apparatus including a housing to accommodate at least one tray therein, the housing having a first side and a second side, an ultraviolet (UV) light source disposed in the housing and configured to emit UV light towards the tray, and a plurality of doors including a first door and a second door disposed on the first side and the second side of the housing, respectively, in which the first door and the second door are configured to be opened in a direction away from the housing.

A surgical instrument for use with a robotic system that has a control unit and a shaft portion that includes an electrically conductive elongated member that is attached to a portion of the robotic system. The elongated member is configured to transmit control motions from the robotic system to an end effector.