Abstract: The present invention relates to an electromagnetic machine comprising: rotation shaft; a stator comprising a multi-phase winding wire; a mover (rotor 1) comprising the multi-phase winding wire and spaced apart from the stator at a preset interval; and a controller for independently controlling a first magnetic field of the stator and a second magnetic field of the mover (rotor 1). The electromagnetic machine according to the present invention can resolve, by means of the mover (rotor 1) and the wound-type stator that can be independently and actively controlled, a torque issue at start-up or when needed and, thereby, has the effects of producing a maximum driving torque while having a minimum size, and of maximizing efficiency.

Abstract: The present invention relates to an electromagnetic machine comprising: rotation shaft; a stator comprising a multi-phase winding wire; a mover (rotor 1) comprising the multi-phase winding wire and spaced apart from the stator at a preset interval; and a controller for independently controlling a first magnetic field of the stator and a second magnetic field of the mover (rotor 1). The electromagnetic machine according to the present invention can resolve, by means of the mover (rotor 1) and the wound-type stator that can be independently and actively controlled, a torque issue at start-up or when needed and, thereby, has the effects of producing a maximum driving torque while having a minimum size, and of maximizing efficiency.

Abstract: The present invention relates to a coil arrangement and a moving field electromagnetic machine using same, the coil arrangement being characterized by comprising a first coil arrangement and a second coil arrangement that are formed spaced a predetermined distance apart from each other and have a mirror image in the spaced apart direction, wherein: the first coil arrangement includes at least one first half cycle and at least one second half cycle that are formed adjacent to each other; the first half cycle includes at least two coils having currents flowing in different directions; and the first half cycle and the second half cycle have a mirror image in the direction in which the first and second half cycles are adjacent, thereby maximizing efficiency and increasing power by minimizing the magnetic flux leakage and the core loss.

Abstract: The present invention relates to an electromagnetic machine comprising: rotation shaft; a stator comprising a multi-phase winding wire; a mover (rotor 1) comprising the multi-phase winding wire and spaced apart from the stator at a preset interval; and a controller for independently controlling a first magnetic field of the stator and a second magnetic field of the mover (rotor 1). The electromagnetic machine according to the present invention can resolve, by means of the mover (rotor 1) and the wound-type stator that can be independently and actively controlled, a torque issue at start-up or when needed and, thereby, has the effects of producing a maximum driving torque while having a minimum size, and of maximizing efficiency.

Abstract: A scintillating module is provided which includes a first scintillating layer including a plurality of scintillators extending in a first direction; a second scintillating layer including a plurality of scintillators extending in a second direction and stacked in a third direction with respect to the first scintillating layer, wherein the first, second and third directions are orthogonal to each other.

Abstract: Provided is an analysis apparatus for a high energy particle and an analysis method for a high energy particle. The analysis apparatus for the high energy particle includes a scintillator generating photons with each unique wavelength by the impinging with a plurality of kinds of accelerated high energy particles, a parallel beam converting unit making the photons proceed in parallel to one another, a diffraction grating panel making the photons proceeding in parallel to one another enter at a certain angle, and refracting the photons at different angles depending on each unique wavelength, and a plurality of sensing units arranged on positions where the photons refracted at different angles from the diffraction grating panel reach in a state of being spatially separated, and detecting each of the photons.

Abstract: Provided are an ion generation target and a treatment apparatus including the target. The treatment apparatus includes a grid having a net shape of nano wires, an ion generation thin film attached to a side of the grid and generating ions by means of an incident laser beam, and a laser for emitting a laser beam into the nano wire of the grid to generate ions from the ion generation thin film and project the ions onto a tumor portion of a patient. The laser beam emitted into the nano wire forms a near field, the intensity of which is higher than that of the laser beam through a nanoplasmonics phenomenon, and the near field emits the ions from the ion generation thin film.

Abstract: Provided are a carbon ion generation target and a treatment apparatus including the same. The treatment apparatus includes a support member, a carbon ion generation target fixed to the support member, and a laser for irradiating laser beam into the carbon ion generation target to generate carbon ions from the carbon ion generation target, thereby projecting the carbon ions onto a tumor portion of a patient. Here, the carbon ion generation target includes a substrate and carbon thin films disposed on the substrate.

Abstract: The present invention relates to an apparatus for generating an ultra-short ultra-high intensity pulse laser, comprising: a pulse laser providing unit which generates an ultra-short ultra-high intensity pulse laser, stretches pulse width, then selects and provides only a pulse laser having a predetermined polarizing angle; a polarization characteristic adjusting unit which divides the pulse laser provided by the pulse laser providing unit into S-polarizing component light and P-polarizing component light, varies the phase difference and amplitude difference between the S-polarizing component light and the P-polarizing component light, and combines the two types of light to generate a pulse laser with varied polarization characteristics; and a pulse compression unit which compresses the pulse width of the pulse laser, the polarization characteristics of which are varied by the polarization characteristic adjusting unit, and outputs the pulse laser.

Abstract: Provided is an analysis apparatus for a high energy particle and an analysis method for a high energy particle. The analysis apparatus for the high energy particle includes a scintillator generating photons with each unique wavelength by the impinging with a plurality of kinds of accelerated high energy particles, a parallel beam converting unit making the photons proceed in parallel to one another, a diffraction grating panel making the photons proceeding in parallel to one another enter at a certain angle, and refracting the photons at different angles depending on each unique wavelength, and a plurality of sensing units arranged on positions where the photons refracted at different angles from the diffraction grating panel reach in a state of being spatially separated, and detecting each of the photons.

Abstract: Provided are a carbon ion generation target and a treatment apparatus including the same. The treatment apparatus includes a support member, a carbon ion generation target fixed to the support member, and a laser for irradiating laser beam into the carbon ion generation target to generate carbon ions from the carbon ion generation target, thereby projecting the carbon ions onto a tumor portion of a patient. Here, the carbon ion generation target includes a substrate and carbon thin films disposed on the substrate.

Abstract: The present invention relates to an apparatus for generating an ultra-short ultra-high intensity pulse laser, comprising: a pulse laser providing unit which generates an ultra-short ultra-high intensity pulse laser, stretches pulse width, then selects and provides only a pulse laser having a predetermined polarizing angle; a polarization characteristic adjusting unit which divides the pulse laser provided by the pulse laser providing unit into S-polarizing component light and P-polarizing component light, varies the phase difference and amplitude difference between the S-polarizing component light and the P-polarizing component light, and combines the two types of light to generate a pulse laser with varied polarization characteristics; and a pulse compression unit which compresses the pulse width of the pulse laser, the polarization characteristics of which are varied by the polarization characteristic adjusting unit, and outputs the pulse laser.

Abstract: Provided are a carbon ion generating device and a tumor treatment apparatus using the same. The carbon ion generating device includes a carbon nanostructure, a carbon emitting structure, an ionizing structure, and an accelerator. The carbon emitting structure is configured to induce an emission of carbon atoms from one end of the carbon nanostructure. The ionizing structure is configured to ionize the emitted carbon atoms. The accelerator is configured to accelerate the ionized carbon atoms.

Abstract: A treatment apparatus using proton includes a proton generation unit and a magnet. The proton generation unit projects proton into a tumor site of a patient, and the magnet forms a magnetic field around the patient. The proton conducts a spiral motion due to collision with atom of the tumor site and Lorenz force generated by the magnetic field.

Abstract: A treatment apparatus using proton includes a proton generation unit and a magnet. The proton generation unit projects proton into a tumor site of a patient, and the magnet forms a magnetic field around the patient. The proton conducts a spiral motion due to collision with atom of the tumor site and Lorenz force generated by the magnetic field.

Abstract: Provided is a treatment apparatus including a target material for generating protons. The treatment apparatus includes a cylindrical bore member having an inner space to receive a patient; a proton generating target material provided to an inner surface of the bore member; and a laser adapted to supply a laser beam to the proton generating target material so that protons are generated from the proton generating target material and projected to a tumor site of the patient. The proton generating target material includes a supporting film and a hydrogenated amorphous silicon (a-Si:H) film provided on the supporting film.

Abstract: Provided are a carbon ion generating device and a tumor treatment apparatus using the same. The carbon ion generating device includes a carbon nanostructure, a carbon emitting structure, an ionizing structure, and an accelerator. The carbon emitting structure is configured to induce an emission of carbon atoms from one end of the carbon nanostructure. The ionizing structure is configured to ionize the emitted carbon atoms. The accelerator is configured to accelerate the ionized carbon atoms.

Abstract: A method for detecting an antigen, an apparatus for detecting an antigen using the same, and a microfluidic chip using the same are disclosed. The method for detecting an antigen, includes: binding a first antibody and nano-beads to generate antibody nano-beads; binding the generated antibody nano-beads and an antigen to generate antigen-antibody nano-beads; forming at least one of an electric field and a magnetic field on the generated antigen-antibody nano-beads to bind the generated antigen-antibody nano-beads and a second antibody; and detecting the antigen-antibody nano-beads bound to the second antibody. Thus, when nano-beads affected by an electromagnetic field exist within the electromagnetic field that temporally and spatially changes, the nano-beads move according to non-uniformity of the electromagnetic field. In particular, an active mixing can be performed by using the electromagnetic field which is spatially non-uniform and changes temporally, a reaction time can be reduced.

Abstract: A minimally invasive particle beam cancer therapy apparatus that can be inserted into the body and deliver a particle beam onto a cancer cell generated in the body. The minimally invasive particle beam cancer therapy apparatus may include: a particle beam delivery system delivering a particle beam onto a diseased part formed inside a therapy subject, the particle beam delivery system being partially inserted into the therapy subject when delivering the particle beam; a medical apparatus body shaped like a pipe having a predetermined length and physically connected to the particle beam delivery system, the medical apparatus being partially inserted into the therapy subject in a longitudinal direction along with the particle beam delivery system being partially inserted into the therapy subject to help the insertion of the particle beam delivery system into the therapy subject; and a control system controlling a driving operation of the particle beam delivery system.