Patent Number: 
Section: claims

1. A neutron conversion foil for being used in a neutron detector, said neutron conversion foil being configured to be arranged in a scintillator volume and comprising a substrate having a first side and a second side,whereby said substrate is covered at least on one of said first side and said second side with a neutron conversion layer made of a neutron reactive material and being capable of capturing neutrons to thereafter emit light and/or charged particles to be detected by a light sensing device, andwhereby said neutron conversion layer and substrate are transparent to light originating from conversion of the neutrons, and are configured to be arranged such that the light originating from the conversion of the neutrons can pass through and away from the substrates and neutron conversion layers of one or several of said neutron conversion foils and thereafter be collected and detected by the light sensing device. 2. The neutron conversion foil as claimed in claim 1, wherein said substrate is covered on said first side and said second side with a neutron conversion layer made of a neutron reactive material and being capable of capturing neutrons to thereafter emit light and/or charged particles. 3. The neutron conversion foil as claimed in claim 1, wherein said neutron conversion layer contains Li-6 or B-10. 4. The neutron conversion foil as claimed in claim 3, wherein said neutron conversion layer comprises a coating applied to the substrate, wherein the coating comprises LiF and a suitable binder in a weight ratio between 1:1 and 15:1, and that appropriate measures such as LiF nanosizing or refractive index matching are performed to ensure high transparency. 5. The neutron conversion foil as claimed in claim 3, wherein said neutron conversion layer has a layer thickness of between 1 μm and 40 μm, especially between 3 μm and 20 μm. 6. The neutron conversion foil as claimed in claim 1, wherein said substrate is a transparent PET foil. 7. The neutron conversion foil as claimed in claim 6, wherein said transparent PET foil has a thickness of between 2 μm and 19 μm. 8. The neutron conversion foil as claimed in claim 1, wherein each of said neutron conversion layers is overcoated with a wavelength shifting layer being capable of shifting short wavelength light impinging upon it and reemitting light with a wavelength to which said neutron conversion foil is transparent. 9. The neutron conversion foil as claimed in claim 8, wherein said wavelength shifting layer contains Tetra Phenyl Butadiene (TPB), an organic wavelength shifter, or an organo silicate compound. 10. The neutron conversion foil as claimed in claim 9, wherein said wavelength-shifting layer has a layer thickness of between 0.05 μm and 1 μm, especially between 0.05 μm and 0.2 μm. 11. The neutron conversion foil as claimed in claim 1, wherein that said substrate is a mesh. 12. A neutron detecting device comprising:a scintillation volume filled with a scintillating material such as a noble gas;at least one light sensing device in optical contact with the scintillating volume;one or more neutron conversion foils, the neutron conversion foils each comprising a substrate having a first side and a second side, whereby said substrate is covered at least on one of said first side or said second side with a neutron conversion layer made of a neutron reactive material and being capable of capturing neutrons to thereafter emit light and/or charged particles to be detected by the at least one light sensing device, and whereby said neutron conversion layer and substrate are transparent to light originating from conversion of the neutrons, and are configured to be arranged such that the light originating from the conversion of the neutrons can pass through and away from the substrate and neutron conversion layers of one or several of said neutron conversion foils and thereafter be collected and detected by the at least one light sensing device,wherein said one or more neutron conversion foils are positioned in said scintillation volume and in optical contact with said scintillating material, and are configured to be arranged such that charged conversion products arising from neutron capture in said one or more neutron conversion foils escape into said scintillation volume and produce light, to which said one or more neutron conversion foils is transparent, and wherein the produced light is detected by the light sensing device. 13. The neutron detecting device as claimed in claim 12, wherein at least one light-sensing device is provided in optical contact with said scintillation volume. 14. The neutron detecting device as claimed in claim 13, wherein said at least one light sensing device is a solid state light sensor, especially one of a silicon photomultiplier (SiPM) or pixelated Geiger mode avalanche photodiode. 15. The neutron detecting device as claimed in claim 13, wherein said scintillation volume is composed primarily of a noble gas such as helium, argon or xenon or a mixture of noble gases, such as helium doped with xenon, and/or wherein said scintillation volume contains predominantly PVT or a liquid scintillator, thereby allowing the simultaneous measurement of gammas and neutrons. 16. The neutron detecting device as claimed in claim 15, wherein said scintillation volume is predominantly filled with helium, thereby allowing the simultaneous measurement and distinction of fast neutrons, thermal neutrons, and/or photons and electrons produced by the interaction of photons with a detector wall, and/or with xenon, thereby allowing gamma spectrometry to be performed while also measuring neutrons. 17. The neutron detecting device as claimed in claim 14, wherein said at least one solid state light sensor is arranged within said scintillation volume. 18. The neutron detecting device as claimed in claim 15, wherein an in-situ gas purification device such as a getter is immersed in the gas of said scintillation volume, thereby assuring a stable gas composition. 19. The neutron detecting device as claimed in claim 13, wherein said scintillation volume is surrounded by a highly reflective material in the area of which a plurality of light sensing devices can be interspersed. 20. The neutron detecting device as claimed in claim 12, wherein plural neutron conversion foils are arranged in parallel in said scintillation volume. 21. The neutron detecting device as claimed in claim 12, wherein said neutron detecting device is part of a detector system, and wherein a plurality of detector subunits are connected with a control center for evaluating detector data via a wireless network. 22. The neutron detecting device as claimed in claim 21, wherein said neutron detecting device is part of at least one of said detector subunits. 23. The neutron detecting device as claimed in claim 22, wherein said neutron detecting device is connected within said detector subunit to a single board computer, which itself is connected to a network unit and comprises detector software and a data aggregation software/network protocol. 24. The neutron detecting device as claimed in claim 23, wherein a GPS unit for determining the actual position of said detector subunit is connected to said single board computer. 25. A method for operating the neutron detecting device according to claim 12, wherein signals arising from a neutron conversion in said one or more neutron conversion foils are discerned from signals arising from said scintillation volume by pulse shape discrimination, whereby the signals involving light emitted by said one or more neutron conversion foils have a different time structure than the signals from said scintillation volume. 26. The method as claimed in claim 25, wherein light signals arising directly or indirectly from said neutron conversion in said one or more neutron conversion foils are discerned from signals from said scintillation volume alone by pulse shape discrimination, whereby the signals from neutron conversion have a different time structure than the signals from said scintillation volume. 27. A method for operating the neutron detecting device according to claim 12, wherein the presence, the intensity and/or the type of gamma radiation interacting with the scintillating volume is determined by analyzing the distribution of the energy spectrum of the interaction events accumulated during a predetermined period of time of operation, especially in a range from 1 to 100 seconds. 28. A method for operating the neutron detecting device according to claim 12, wherein two overlapping spectral distributions resulting from the simultaneous interaction of gamma radiation and neutron radiation with the scintillating volume and/or the converter foil and being accumulated during a predetermined period of time of operation, especially in a range from 1 to 100 seconds, are analyzed employing statistical methods, whereby a net neutron count rate can be determined by subtracting the spectral response obtained by the gamma radiation from the total spectrum. 29. The neutron conversion foil as claimed in claim 1, wherein the neutron conversion foil comprises a flexible foil. 30. The neutron conversion foil as claimed in claim 1, wherein the neutron conversion foil comprises a foil which is sufficiently thin, such that deposition of energy by gamma radiation is reduced.