A fragmentation system for electrodynamic fragmentation of material contains a feed and an outlet for transporting material along a transport path in a transport direction. At least one high-voltage pulse source is provided, each of the high-voltage pulse sources contains at least one first electrode and at least one second electrode for generating a high-voltage discharge in a discharge chamber. The transport path has a fractionation section, and the fractionation section extends through the discharge chamber. A selection device for selectively extracting the material on the transport path is provided in order to channel material and/or fragments of the material having a diameter smaller than a minimum diameter past at least one portion of one of the fractionation sections.

A disassembling apparatus that shatters an object by means of pulsed discharge includes a container that can be filled with a liquid, an anode that is disposed within the container, a cathode that is disposed such that the object can be placed so as to straddle the anode and the cathode, object scattering prevention means that encloses an object disassembling region above the anode and the cathode, and a pulsed power supply that applies a high voltage pulse between the anode and the cathode.

A method for fragmenting and/or weakening of pourable material by means of high-voltage discharges is disclosed. Thereby, a material flow of the pourable material is, immersed in a process liquid, guided past a high-voltage electrode assembly with one or more high-voltage electrodes, while high-voltage punctures through the material are produced by means of charging of the high-voltage electrodes with high-voltage pulses. The zone of the material flow in which the high-voltage punctures through the material are produced is delimited laterally by substantially unmoved zones of the same material as viewed in a guiding-past direction. With the disclosed method, it becomes possible to fragment and/or weaken pourable material in a continuous process by means of high-voltage punctures in a low-wear and low-contamination manner.

A method for fragmenting and/or weakening pourable material includes guiding a material stream of pourable material immersed in a process liquid along an annular or arcuate channel past a high-voltage electrode assembly. The high-voltage electrode assembly, which includes one or more generators, generates high-voltage punctures through the material flow. Material is supplied to the material stream upstream of the high voltage electrode arrangement. Material is guided away from the material stream downstream of the high-voltage electrode assembly.

An electronic device incorporating a high voltage power supply connected to a pair of metal plates spaced to maintain a continuous high current arc of electricity creating an Ion Plasma discharge for the purpose of vaporizing documents placed between the plates. Magnetic containment coils around the outside of the metal plates are phase synchronized to the magnetic field created by the Ion Plasma arc to maintain the position of the arc between the plates and to direct the position of the arc in a predetermined pattern to search for any material between the plates that has not been disintegrated.

A homogenized and integrated device with a coaxial line and double-high pressure cylinder, includes a long oil cylinder, two main connecting sleeves, two high pressure cylindrical homogenized main bodies, two auxiliary connecting sleeves and two short oil cylinders. The two main connecting sleeves, two high pressure cylindrical homogenized main bodies, two auxiliary connecting sleeves and two short oil cylinders are respectively and symmetrically arranged at two ends of the long oil cylinder and are assembled with the long oil cylinder along a same axial line. Each high pressure cylindrical homogenized main body is integrally connected with the long oil cylinder by virtue of one of the main connecting sleeves. Each high pressure cylindrical homogenized main body is integrally connected with the corresponding short oil cylinder by virtue of one of the auxiliary connecting sleeves.

The invention relates to the field of excavation systems, and more particularly to excavation systems including tools for excavation by electric pulses. An excavation system of the invention comprises a support frame (34), a hydraulic circuit with a pump, and first and second excavation tools. One of said first and second excavation tools is a mechanical excavation tool (1) having a hydraulic actuator and a mounting interface with at least one mechanical fastener member and at least one hydraulic coupling in fluid flow communication with said hydraulic actuator, while the other one of said first and second excavation tools is a tool (1) for excavation by electric pulses, comprising an electricity generator (3) with a rotary shaft for generating electricity from rotation of the rotary shaft, a hydraulic motor coupled to said rotary shaft to drive rotation of the rotary shaft, and an electronic power module (4) electrically connected to the electricity generator (3) in order to be powered by the electricity generator (3) so as to generate electric pulses of instantaneous power that is higher than an instantaneous power of the electricity generator (3), a plurality of electrodes (5a, 5p) including at least one electrode (5a) connected to said electronic power module (4), the electrodes being arranged on said front face, and a mounting interface (14) with at least one mechanical fastener member (22), and at least one hydraulic coupling (20) in fluid flow communication with said hydraulic motor (2). Each of the mounting interfaces of the first and second excavation tools is suitable for releasably mounting the corresponding excavation tool in alternation under the support frame (34) of the excavation system, with the corresponding hydraulic coupling in fluid flow communication with said hydraulic circuit of the excavation assembly.

The invention relates to a method for treating shell-fruits (3), in particular for producing shell-fruits (3) with improved shelling properties in comparison to untreated shell-fruits (3). The invention further relates to a device (1) for treating shell-fruits (3), in particular for producing shell-fruits (3) with improved shelling properties in comparison to untreated shell-fruits (3), comprising a hermetically sealable treatment chamber (2) for conditioning the shell-fruits (3). In order to provide a method and a device for treating shell-fruits which do not damage the contents of the kernel and simultaneously permit improved shelling of the shell-fruits and the opened shell to be better separated from the kernel, the method according to the invention comprises softening the shell of the shell-fruits (3) by applying an electric field, and the device according to the invention comprises at least one capacitor (4) for generating an electric field in the treatment chamber (2).

A method for processing, namely recycling, a workpiece made of electroplated plastic. In which method a coating is removed from the workpiece by a fragmentation unit by applying the electrohydraulic effect to a suspension containing plastic granules and containing coating granules. The suspension is dewatered, and a magnetic separator is used to separate the plastic granules from the coating granules by means of magnetic separation.

A silicon rod crushing method relatively moves an application position of high-voltage pulse discharge to a silicon rod in a longitudinal direction thereof while rotating the silicon rod to thereby crush the silicon rod.