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    • 专利摘要:
    four-sided imaging system and smuggling detection method the present invention provides a four-sided scanning system for vehicles that uses a combination of transmission and backscatter-based x-ray imaging to obtain material discrimination. in one embodiment, the system is designed as a mobile driving system, which can be folded and stowed in a truck and can be conveniently implemented anywhere, when needed.
    公开号:BR112012000884B1
    申请号:R112012000884-6
    申请日:2010-07-13
    公开日:2020-09-24
    发明作者:Andreas F. Kotowski;Edward James Morton
    申请人:Rapiscan Systems, Inc.;
    IPC主号:
    专利说明:

    [0001] This application is based on Provisional Patent Application No. US 61 / 224,938 filed on July 13, 2009, and is hereby incorporated by reference in its entirety.
    [0002] The present invention is partly a continuation of US Patent Application 12 / 396,568, entitled "Single bar load scanning system", and filed on March 3, 2009, which is partly a continuation of Patent Application no. US 11 / 948,814, entitled "Single bar load scanning system", filed on November 30, 2007, and now issued US Patent 7,517,149, which is a continuation of US Patent 7,322,745, entitled "Load scanning system single bar "filed on August 9, 2004, which is based, by priority, on US Provisional Patent Application No. 60 / 493,935, filed on August 8, 2003 and is partly a continuation of the Provisional Patent Application US 10 / 201,543, entitled "Portable Self-contained Inspection System and Method", filed July 23, 2002 and now US Patent 6,843,599. The '591 application is still based on Provisional Patent Application No. US 61/014, 814, filed on December 19, 2007, by priority.
    [0003] The present invention is also partly a continuation of US Patent Application 12 / 395,760, entitled "Single bar load scanning system", and filed on March 2, 2009, which is partly a continuation of the Patent Application US 12 / 051,910, entitled "Single-bar load scanning system", and filed on March 20, 2008, now issued US Patent 7,519,148, which is a continuation of US Patent 7,369,463, of the same title, filed in January 12, 2007, which is a continuation in part of US Patent 7,322,745.
    [0004] The present invention is a partial continuation of US Patent Application 12 / 339,591, entitled "Rotary bar load scanning system", filed on December 19, 2008, which is a partial continuation of the US Patent Application 11 / 948,814, described above and also partly a continuation of US Patent Application 12 / 051,910, described above.
    [0005] The present invention is also partly a continuation of US Patent Application 12 / 753,976, entitled "Self-contained mobile inspection system", and filed on April 5, 2010, which is partly a continuation of 12 / 349,534, with the same title, and filed on January 7, 2009 (and now issued US Patent 7,720,195), which is a continuation of US Patent Application 10 / 939,986, entitled "Self-contained mobile inspection system", and filed on September 13, 2004, which is a continuation in part of 10 / 915,687 (issued as a Patent in US 7,322,745), which is a continuation in part from 10 / 201,543 (issued as a Patent in US 6,843,599) and is still based on Provisional Patent Application No. US 60/502, 498, filed on September 12, 2003, by priority.
    [0006] The present invention is also partly a continuation of US Patent Application 12 / 263,160, entitled "Cargo Scanning System", and filed on October 31, 2008, which is still based on US Provisional Patent Application 60 / 984,786, filed on November 2, 2007, by priority, and is a continuation in part of US Patent 7,322,745.
    [0007] The present invention is also partly a continuation of US Patent Application 12 / 675,471, entitled "Scanning Systems", and filed on February 26, 2010, which is a National Stage entry for PCT / GB08 / 02897.
    [0008] The present invention is also partly a continuation of US Patent Application 12 / 784,630, entitled "Compact Load Mobile Scanning System", and filed on May 21, 2010, which is still based on the Provisional Patent Application on US 61 / 180,471, of the same title, and deposited on May 22, 2009, as a priority.
    [0009] All patent applications listed above are hereby incorporated by reference in their entirety. FIELD OF THE INVENTION
    [0010] The present invention relates to X-ray detection and scanning systems for sorting cars, buses, larger vehicles, and cargo containers for suspicious trade and illicit substances. More specifically, the present invention relates to a four-sided imaging system that provides high detection performance using a combination of backscatter and transmission image sensors. BACKGROUND OF THE INVENTION
    [0011] X-ray systems are used for medical, industrial and safety inspection purposes, because they can cost-effectively image indoor spaces not visible to the human eye. Materials exposed to X-ray radiation absorb different amounts of X-ray radiation and therefore attenuate an X-ray beam to varying degrees, resulting in a transmitted or backscattered level of radiation that is characteristic of the material. The attenuated or backscattered radiation can be used to generate a useful representation of the content of the irradiated object. A typical single X-ray energy configuration used in safety inspection equipment may have a fan-shaped beam or X-ray scan that is transmitted through or backscattered by the inspected object. The absorption or backscattering of X-rays is measured by detectors after the beam has passed through the object and the image is produced from its contents and presented to an operator.
    [0012] Trade fraud, smuggling and terrorism have increased the need for such non-intrusive inspection systems in applications ranging from inspecting vehicles parked on the sidewalk to scanning in congested or high-traffic ports, because the transport systems that efficiently provide circulation goods across borders, also offer opportunities for the inclusion of smuggled items such as weapons, explosives, illicit drugs and precious metals. The term port, while generally accepted as referring to a port, also applies to a land border crossing or any port of entry.
    [0013] With an increase in global trade, port authorities require additional moorings and associated container storage space. Additional space requirements are typically met by introducing tall stacks of containers, expanding ports along the coast, or moving inland. However, these situations are not typically viable. Space is, in general, a substantial and scarce demand. Existing ports operate under a routine that is not easily modified without disturbing the entire infrastructure of the port. The introduction of new procedures or technologies often requires a substantial change in existing port operating procedures in order to contribute to the port's performance, efficiency and operability.
    [0014] With limited space and a need to expand, finding the right space to accommodate additional inspection facilities along the normal process route remains difficult. In addition, the locations selected are not necessarily permanent enough for port operators to commit to the long-term installation of inspection equipment. In addition, systems that incorporate high-energy X-ray sources, or linear accelerators (LINAC), require a major investment in protective material (usually in the form of concrete formations or buildings) or the use of exclusion (dead space) around the building itself. In both cases, the building footprint is significant, depending on the size of the cargo containers to be inspected.
    [0015] A mobile inspection system offers a suitable solution for the need for improved, flexible inspection capabilities. As the system is relocatable and investing in permanent construction to accommodate the equipment is avoided, site allocation becomes less of an issue and the introduction of such a system becomes less disturbing. In addition, a mobile X-ray system provides operators, through higher throughput, the ability to inspect a greater variety of cargo, shipments, vehicles and other containers.
    [0016] Conventional relocatable inspection systems generally comprise at least two bars, where one bar will contain a plurality of detectors and the other bar will contain at least one X-ray source. The detectors and X-ray source work in unison to scan the load on the moving vehicle. In conventional single-bar relocatable inspection systems, the X-ray source is located on a truck or flat table and the detectors on a bar structure extending out of the truck. These systems are characterized by moving scan engine systems in which the detector source system moves with respect to a fixed object to be inspected. In addition, the detectors and the radiation source are either mounted on a moving bed bar or a vehicle in such a way that they are integrally connected with the vehicle. This limits the flexibility to dismantle the entire system for optimal portability and adjustable deployment to accommodate a wide variety of different sized cargo, shipments, vehicles and other containers. As a result of these systems, it can be complicated to implement and put several disadvantages and limitations. Conventional systems are disadvantageous in that they suffer from a lack of rigidity, are difficult to implement, and / or have smaller fields of view.
    [0017] Thus, there is a need for improved control methods and systems integrated into a fully self-contained, legitimate over-the-road vehicle that can be brought to a location and quickly deployed for inspection. The improved method and system can therefore serve multiple inspection sites and set up surprise inspections to prevent smuggling traffickers who normally bypass border smuggling operations that have difficult interdiction measures for smoother crossings with lesser inspection capabilities. In addition, there is an additional need for methods and systems that require minimal footprint to perform inspection and that use a sufficient range of radiation energy spectrum to encompass safe and effective scanning of commercial vehicles, as well as substantially loaded 20-foot cargo containers. or 40 feet ISO. It is important that the scan be carried out without compromising the integrity of the cargo and should, ideally, be easily detachable in a variety of environments ranging from airports to ports of entry, where a single-sided inspection mode needs to be used, due to congested environments. Similar needs are addressed in US Patent 6,543,599, entitled "Self-contained portable inspection system and method", which is hereby incorporated by reference in its entirety. In addition, there is a need for improved methods and systems that can provide comprehensive load scanning in portable and stationary configurations.
    [0018] In addition, in mobile load inspection systems known in the art, the boom structures are typically heavy, thus making the overall weight of the sweeping system close to, or even over, the permissible axle load limits. In addition, the bars are bulky when stowed in such a way that the vehicle is about 4m high above road level. This makes a mobile sweeping system not only difficult to maneuver, but it also restricts movement in different territories, due to the road restrictions applicable on the weight of the car. Therefore, there is also a need for a sweeping system that can be stowed away in a relatively compact area so that it can be easily transported on the road as well as by air. In addition, there is also a need for a sweeping system that is lightweight and has a low height and center of gravity in the stowed position, thus allowing road transport, even in difficult, steep and hill areas.
    [0019] In addition, inspection usually takes place from just three directions or less. For example, a transmission X-ray system will be deployed in a sniper-side or top-sniper configuration, while a backscatter system is generally only available in one-sided or three-sided configurations.
    [0020] Therefore, what is also needed is a four-sided imaging system, which provides high detection performance using a combination of backscatter and transmission image sensors. SUMMARY OF THE INVENTION
    [0021] In one embodiment, the present invention is a scanning system for cargo inspection, comprising: a portal defining an inspection zone, said portal comprising a first vertical side, a second vertical side, an upper horizontal side, and a horizontal base defined by a ramp adapted to be driven over by a vehicle, a first X-ray source arranged on at least one of the first vertical side, second vertical side or upper horizontal side for the generation of an X-ray beam within the area of inspection for the vehicle, a first set of transmission detectors disposed inside the portal to receive the X-rays transmitted through the vehicle, a second X-ray source disposed inside the ramp of said portal for the generation of a beam of X-ray for the lower portion of the vehicle, and a second set of detectors arranged inside the ramp of said portal for the reception of X-rays that are backscattered from the video eiculus.
    [0022] In one embodiment, the system can be retracted. In one embodiment, the ramp comprises a hinged base platform for a first angled surface and a second angled surface and in which, when said system is retracted, the first angled surface and the second angled surface are rotated upwards.
    [0023] In one embodiment, the upper horizontal side is connected to said first vertical side at a first end and to said second vertical side at a second end, and the first X-ray source is arranged in a midpoint shape between the said first end and said second end.
    [0024] In one embodiment, the first X-ray source is a high energy source having an energy ranging from 100 kVp to 2 MV. In another embodiment, the second X-ray source is a low energy source having an energy ranging from 60 kVp to 250 kVp.
    [0025] In one embodiment, the system further comprises a controller, wherein said controller is adapted to activate the first X-ray source only when the second X-ray source is inactive.
    [0026] In one embodiment, the system further comprises a primary rotating collimator placed adjacent to said second X-ray source, and a secondary static collimator placed adjacent to said rotating collimator and parallel to the inspection surface, wherein said secondary collimator is adapted for generate a first irradiation area in the center of the inspection area and a second irradiation area on a periphery of the inspection area and in which the said second irradiation area is larger than the first irradiation area.
    [0027] In one embodiment, the system further comprises backscatter detectors on at least one of said first vertical side, second vertical side, and said upper horizontal side. In another embodiment, the backscatter X-ray source is not arranged with said backscatter detectors on at least one of said first vertical side, second vertical side, and said upper horizontal side.
    [0028] In another embodiment, the present invention is a method for inspecting a vehicle, comprising: providing a portal defining an inspection zone, said portal comprising a first vertical side, a second vertical side, an upper horizontal side, and a defined horizontal base by a ramp adapted to be driven over by a vehicle; signal a vehicle to drive along the ramp; irradiate a vehicle with X-rays from a first source arranged on one side of the portal; detect the X-rays transmitted through the vehicle, use transmission detectors placed inside the portal, to produce a first representative signal of the vehicle and its contents; irradiate the lower portion of the vehicle with X-rays from a second source disposed within the ramp; detect X-rays diffused backwards from the vehicle, use the backscatter detectors located inside the ramp, to produce a second representative signal of the vehicle and its contents; and correlating said first output signal and said second output signal to produce a visual image of the vehicle and its contents. In one embodiment, the first X-ray source is operated when said second X-ray source is inactive.
    [0029] In yet another embodiment, the present invention is a scanning system for inspecting a vehicle, comprising: a portal defining an inspection zone, said portal comprising a first vertical side and a second vertical side spaced from each other and each having a side top; a third side connecting said two top sides; a ramp over adapted to be driven over by a vehicle; an X-ray source arranged on one side of the portal to generate an X-ray beam for the inspection area; a first set of detectors disposed within the portal for the reception of X-rays transmitted through the vehicle; a second set of detectors disposed inside the ramp and the first, second and third sides of said portal for receiving backscattered X-rays from the vehicle, and an image processor to receive output signals from said first and second set detectors and superimpose said exit signals on top of a visual image of the vehicle and its contents.
    [0030] In one embodiment, the first set of detectors is arranged on at least two of the same sides of the portal as the second set of detectors. In one embodiment, the first set of detectors comprises a first detector and a second detector adapted to measure an X-ray energy component transmitted through the vehicle in a range of 0 keV to 50 keV and 20 keV to 2 00 keV, respectively, and a third detector to measure an X-ray energy component transmitted through the vehicle in a range of 10 0 keV to 2 MeV. In one embodiment, the three detectors are in a stacked configuration. In one embodiment, a difference between an output from the third detector and a sum of outputs from the first and second detectors is used to achieve material discrimination.
    [0031] In one embodiment, the system also comprises a sensor to measure the speed of the vehicle as it passes through the portal. In one embodiment, the system further comprises a controller in which said controller is in data communication with the sensor and receives vehicle speed and in which said controller is adapted to modulate a pulse rate from the X-ray source to achieve a substantially constant dose per unit length of the vehicle under inspection based on speed. BRIEF DESCRIPTION OF THE DRAWINGS
    [0032] These and other features and advantages of the present invention will be appreciated, as they become better understood by reference to the following detailed description when considered in connection with the accompanying drawings, in which: Figure 1 is a schematic representation of the four-sided X-ray imaging system of the present invention; Figure 2 illustrates an orthogonal view of the four-sided X-ray imaging system of the present invention; Figure 3a is a schematic representation of an X-ray imaging system that can be readily retrieved in a first configuration; Figure 3b illustrates an orthogonal view of an embodiment of an X-ray imaging system that can be readily retrieved in a first configuration, as shown in Figure 3a; Figure 3c is a schematic representation of an embodiment of an X-ray imaging system that can be readily retrieved in a second configuration; Figure 3d illustrates an orthogonal view of an X-ray imaging system that can be readily retrieved in a second configuration, as shown in Figure 3c; Figure 3e is a schematic representation of an X-ray imaging system that can be readily retrieved in a third configuration; Figure 3f illustrates an orthogonal view of an embodiment of an X-ray imaging system that can be readily retrieved in a third configuration, as shown in Figure 3e; Figure 4 is an illustration of an embodiment of a triple-stacked detector element; Figure 5 is an integrating circuit diagram of signal processing as signals from each detector element are passed to the integrating circuits; Figures 6a is a graphical representation of the analyzed digital sensor values; Figure 6b is another graphical representation of the analyzed digital sensor values; Figure 7 is an illustration of a modality of a sensor that is capable of collecting backscattered radiation information and generating a backscattering image of a region; Figure 8 is a cross-section representative of an embodiment of an X-ray source that can be used with the present invention; Figure 9 is an illustration of the X-ray beam when it comes in contact with the object under inspection and the subsequent backscattering; Figure 10a is an illustration of an embodiment of the present invention in which a rotary pencil collimator is replaced with a groove rotary collimator; Figure 10b is a graphical representation of the time that a pulsed X-ray source can be triggered to create a corresponding line from an X-ray transmission image without interference from the backscatter detector; Figure 11a is an illustration of another embodiment of the present invention in which the sweep assembly can optionally be integrated with a transport trailer, in a first configuration; Figure 11b is an illustration of another embodiment of the present invention in which the sweep assembly can optionally be integrated with a transport trailer, in a second configuration; Figure 11c is an illustration of another embodiment of the present invention in which the sweep assembly can optionally be integrated with a transport trailer in a third configuration; Figure 11d is an illustration of another embodiment of the present invention in which the sweep assembly can optionally be integrated with a transport trailer, in a fourth configuration; Figure 12 represents another embodiment of the present invention in which a four-sided backscatter detector is mounted around the periphery of the scan volume / tunnel; Figure 13a shows another embodiment of the X-ray system of the present invention with alternative transmission X-ray image geometry; Figure 13b shows another embodiment of the X-ray system of the present invention with alternative transmission X-ray image geometry; Figure 13c shows another embodiment of the X-ray system of the present invention with alternative transmission X-ray image geometry; Figure 14 is an illustration in another embodiment of the present invention in which the system further includes vehicle detection sensors; Figure 15 is a composite image that overlays a backscatter signal with an optical image; and Figure 16 illustrates an exemplary mechanism by which the optical image can be generated by taking an image signal from a mirror. DETAILED DESCRIPTION
    [0033] The present invention is directed to a four-sided imaging system that provides high detection performance using a combination of backscatter and transmission image sensors. The present invention is directed to multiple modalities. Language used in this specification should not be interpreted as a general rejection of any specific modality or used to limit claims beyond the meaning of the terms used in them. Reference will now be made in detail to the specific embodiments of the invention. While the invention will be described in conjunction with specific embodiments, it is not intended to limit the invention to one embodiment.
    [0034] Figure 1 is a schematic representation of an embodiment of a four-sided X-ray imaging system 100. As shown in Figure 1, vehicle 105 drives along a ramp 110 and below an arc 115, which defines an inspection portal. Specifically, the portal is defined by a first side (left) 106, a second side (right) 107, an upper side 108 and a lower platform 109, which is a portion of the ramp. In one embodiment, the ramp 110 comprises a base, a first angled surface leading upwards, to a flat transition point that defines the highest part of the ramp, which also functions as the lower platform 109, and a second angled surface which leads back to the floor. The highest part of the ramp is typically between 50 and 150 mm in height. In one embodiment, arc 115 houses multiple X-ray transmission detectors 117 and at least one X-ray source 119, housed within a housing, shown as 220 in Figure 2.
    [0035] While Figure 1 illustrates the X-ray source 119 as being on the left side 106 of the portal, a person with common skills in the art would appreciate that it could be on the right side 107, with an appropriate reconfiguration of detectors 117. In one embodiment, the first side 106 has a height 106a in a range of 2 meters to 5 meters and a width 106b in a range of 2 meters to 4 meters, the second side 107 has a height 107a in a range of 2 meters to 5 meters and a width 107b in a range of 2 meters to 4 meters, while the upper side 108 has a length 108a in a range of 2 meters to 5 meters and a width 108B in a range of 2 meters to 4 meters, and the lower platform 109 has a length 109a in a range of 2 meters to 5 meters and a width 10 9b in a range of 2 meters to 4 meters, where the width depends on the location of the main opening. In addition, the lower platform 109 has a height in a range of 0.2 meters to 0.4 meters, depending on the width; in one embodiment, a lower platform 109 with a width of 2 meters has a height of 0.2 meters. Therefore, the four sides, each having an inner face towards the inspection region and an outer face directed outwards from the inspection region, define an inspection portal having an inspection area of at least 2 m2 at a maximum of 20 m2.
    [0036] Preferably, the housing housing the X-ray is physically attached to the outer face of the first side 106 and is approximately 1 meter high. The position of the housing depends on the size of the inspection portal. In one mode, the accommodation occupies 20% to 50% of the total height of the first side 106. Thus, in a mode, if the first side 106 is five meters, then the accommodation occupies 20% of the total height. In another modality, if the first side 106 is 2 meters, the accommodation occupies 50% of the height.
    [0037] In one embodiment, a slot or opening 121 is provided on the first side 106, through which X-rays are emitted. Slit or opening 121 extends substantially above the first side 106 at approximately 100% height. In one embodiment, the slot or opening 121 is covered with a thin layer that is easily transparent to an X-ray. In one embodiment, the thin layer is composed of a material, such as aluminum or plastic and also provides an environmental shield.
    [0038] In one embodiment, the housing and X-ray unit still comprise a first collimator near the X-ray source (not shown) and a second collimator near the exit (not shown), described in more detail below.
    [0039] When the X-ray source housing is so positioned, detectors 117 are positioned on the inner face of the second side 107 and the inner face of the upper side 108 and occupy the total height of the second side 107 and the entire length of the upper side 108 , next to the second side 107.
    [0040] In another embodiment, the housing housing the X-ray is physically attached to the outer face of the second side 107 and is approximately 1 meter high. The position of the housing depends on the size of the inspection portal. In a modality, the accommodation occupies 20% to 50% of the total height of the first side 107. Thus, in a modality, if the first side 107 is five meters, then the accommodation occupies 20% of the total height. In another modality, if the first side 107 is 2 meters, the accommodation occupies 50% of the height. As described above with respect to the first side 106, if the housing housing the X-ray is on the second side 107, a slot or opening (not shown) is also provided on the second side 107. The detectors are also similarly positioned on the inner faces of upper side 108 and first side 106, when the housing is on the second side 107.
    [0041] In one embodiment, with a dual display system, a housing housing an X-ray source can be provided on both sides of the first 106 and the second 107 side.
    [0042] Figure 2 illustrates an orthogonal view of system 200, showing both the input ramp 210a and output ramp 210b, as well as the X-ray source housing 220, containing an X-ray source 219.
    [0043] A transmission system in a "sniper-side" configuration, in which the source housing is positioned on the first or second side and emits X-rays to one side of the vehicle, provides a clear inspection of the doors, seats, vehicle compartment engine, luggage compartment and vehicle roof under inspection. However, such an image provides poor inspection of the vehicle's floor plan. A "low-sniper" configuration, in which the source housing is positioned on the lower portion of the first side or second side and emits X-rays from this lower portion, the lower position in the upward direction, provides limited inspection capability for the roof of the vehicle since the X-ray signal for this region is superimposed on the complex and more attenuating X-ray signal of the floor (and passengers), thus resulting in an image of marginal value.
    [0044] In order to provide good penetration of the densest, most highly attenuating objects within the vehicle, such as the engine and luggage compartments, it is advantageous to use a high energy X-ray source, even if tuned to a low intensity output. . A suitable high voltage source has an energy ranging from 100 kVp to 2mV. In one embodiment, at lower energies, a standard X-ray tube source is employed. In another embodiment, at higher energies, a linear pulse accelerator source is employed. In one embodiment of the present invention, the usual operating energies are 200 kVp for the lowest energy and 1 MV for the highest energy.
    [0045] Referring again to Figure 1, in order to provide a high level of control capacity, the ramp 110, over which the vehicle drives, is equipped with, and contains in it, a backscatter X-ray unit comprising a source low energy X-ray, typically having an energy ranging from 60 kVp to 250 kVp, and a plurality of detectors. It should be appreciated that the backscatter unit can be integrated into any floor structure that is mobile and detachable for different locations and on which a car can drive. The backscatter signal from the vehicle floor is strongly influenced by regions of material with a low atomic number. Most regions of the vehicle floor are manufactured from structural materials of high atomic numbers, such as steel, and therefore provide a small backscatter signal. The floor of a car is typically made from relatively thin sealed steel, which typically has a thickness in the range of 1-2 mm. Typically, an X-ray beam can penetrate through this floor and into objects just above it. If materials with a low atomic number are positioned just above the floor, then they will be visible to X-ray backscatter detectors while they would be invisible for standard visual inspection.
    [0046] In operation a four-sided imaging system that combines X-ray backscatter with X-ray transmission image, it is highly advantageous to use a pulsed accelerator based on an X-ray source to generate transmission images with a source of continuous output X-ray for backscatter imaging since the transmission beam X-ray pulse can be programmed to coincide with a period of time when the backscatter system is inactive, thus eliminating any interference between the two systems X-ray and facilitating simultaneous four-sided X-ray inspection. It should also be appreciated that transmission detectors and backscatter detectors are in data communication with a memory and processor that, in conjunction with a controller, generate one or more of transmission and / or backscatter images.
    [0047] Because it is highly advantageous to be able to quickly and non-invasively deploy an X-ray system for security screening of a location, in order to provide an element of surprise in the screening activity, in one embodiment, the present invention is a quickly retractable X-ray system that can be loaded onto a truck for transportation between locations.
    [0048] Figures 3a, 3n, 3c, 3d, 3e and 3f describe a modality of an X-ray imaging system that can be quickly collected in various configurations. Figure 3a is a schematic representation of an X-ray imaging system that can be readily retrieved in a first configuration, in which the system is in a fully implanted position. Quickly retractable X-ray imaging system 300 comprises horizontal X-ray sensor section 305, vertical bar section, 310, driving-over 315 backscatter section and collimator section and vertical bar support 320 through which the transmission beam propagates from source 319. In addition, an X-ray imaging system 300 comprises a ramp 325 (input and output) that allows a vehicle to drive over the X-ray backscatter without problems . Figure 3b illustrates an orthogonal view of an embodiment of an X-ray imaging system that can be readily retrieved as shown in Figure 3a. Figure 3b illustrates source 319, collimator section and vertical support 320, horizontal X-ray sensor section 305, and ramp 325.
    [0049] The quickly deployable system of the present invention can be set up for operation in just a few minutes from arrival at the inspection site. In one embodiment, in order to house the system ready for transport, and referring again to Figure 3a, a set of hydraulic rams or other suitable mechanisms are used to retract vertical bar sections 310 and 320 inwards using hinges 321 and 322 , respectively. Hinges 321 and 322 are positioned, in one embodiment, halfway up to the height of vertical boom sections 310 and 320, respectively. When vertical boom sections 310 and 320 are retracted inward using hinges 321 and 322, horizontal boom section 305 is "reduced" in such a way that it sits on top of retracted vertical boom sections 310, 320.
    [0050] Figure 3c is a schematic representation of an embodiment of an X-ray imaging system that can be readily retracted in a second configuration, in which vertical bar sections 310 and 320 are folded inward and retracted on hinges 321, 322. Figure 3d illustrates an orthogonal view of an X-ray imaging system that can be readily retrieved in a second configuration, as shown in Figure 3c, additionally showing ramp 325 and source 319.
    [0051] Figure 3e is a schematic representation of an embodiment of an X-ray imaging system that can be readily retracted in a third configuration, in which ramp sections 325 are folded up using hydraulic rams or other suitable mechanisms. Figure 3f shows an orthogonal view of an X-ray imaging system that can be readily retracted in a third configuration, as shown in Figure 3e, illustrating ramp 325 that has been folded up, both at the entrance and at the exit . At this point, the system is ready for transport. It should be appreciated that the angled ramp inlet and outlet are hinged to the base platform and able to move in such a way that the tip 32 7 is directed upwards, to achieve system mobility, and to move downwards to form the completed ramp. The base platform preferably houses the aforementioned backscatter system.
    [0052] In order to implement the system, the X-ray image assembly is placed in place and connected. Electricity can be derived from a local electricity supply or from an integrated diesel generator. Hydraulic rams or other suitable mechanisms are then used to fold down the two portions (inlet and outlet) of ramp 325. In one embodiment, the inlet and outlet portions of ramp 325 are folded simultaneously. Once the ramps 325 are down, a second set of hydraulic rams or other suitable mechanisms are used to open vertical boom sections 310 and 320. At this point, the system is ready for use.
    [0053] In one embodiment, the X-ray imaging system of the present invention is capable of providing an image inspector with information regarding the types of material that are present in the object under inspection. In such a wide-open inspection system, a high-energy X-ray beam is required in order to penetrate through the object under inspection. This X-ray beam contains a wide spectrum of X-ray energies ranging from very low energies (typically less than 10 keV) to the highest energy, as determined by the tube or linear accelerator operating voltage (typically in the range of 100 keV at 2 MeV). Due to the unique composition of each material in the object under inspection, each material demonstrates specific attenuation of the X-ray beam, in which this attenuation also comprises an energy-dependent component.
    [0054] Conventionally, a low-energy X-ray beam (typically less than 450 kVp) can produce material discrimination information when a thin front detector measures the low energy component of the beam and a thicker rear detector measures high energy components. of the beam. Here, the two detectors analyze different materials in the object under inspection due to the differential photoelectric absorption of the primary X-ray beam. In addition, in the case of a high energy beam (usually in the range of 1 MV and above), the Compton dispersion fraction increases markedly. Two relatively thick detectors can be used to discriminate between materials in which a first detector is used to absorb most of the signal below approximately 200 keV where the photoelectric effect dominates while a second detector measures only Compton-attenuated signal.
    [0055] Figure 4 is a representation of a triple-stacked detector. As shown in Figure 4, incident X-ray beam 401 passes through two low energy detectors, LEi 405 and LE2 410, before passing through a high energy detector HE 415. Each detector can be formed from a range of X-ray detection materials, such as a scintillator (which converts X-ray energy to optical radiation), a semiconductor (which converts from X-ray energy to conduction band electrons) or a gas ionization (which converts X-ray energy to electron-ion pairs). In one embodiment, the detector configuration described in relation to Figure 4 is used with a 1 to 2 MeV system, where the beam energy is above 450 kVp. In one embodiment, the first LE1 405 detector is capable of measuring a component of X-ray energy transmitted through the object in the range of 0 to 50 keV. In one embodiment, the second detector LE2 410 is capable of measuring a component of X-ray energy transmitted through the object in the range of 20 to 200keV. In one embodiment, the third HE 415 detector is capable of measuring a component of X-ray energy transmitted through the object in the range of 100 keV to 2MeV.
    [0056] In each case, the signals from each detector element are passed to the integrating circuits, as shown in Figure 5. In this modality, but not limited to that modality, a scintillation detector is employed in which an electrical signal generated in a photodiode is converted to a digital value that is directly proportional to the detected X-ray intensity. Scintillator / photodiode / independent integrator circuits are used for each of the three detector elements 405, 410, and 415, shown in Figure 4.
    [0057] Referring again to Figure 5, in operation, the integrator 500 is set with switches 505, 510, and 515 in the open position. Just before X-ray exposure, switch 505 is closed and integration begins. At the end of the exposure, switch 505 is opened and the stored charge is held in the condenser. When the analog-to-digital converter (ADC) is available, switch 515 is closed, and the stored signal is converted to a digital value. At the end of the conversion, switch 515 is opened again and switch 510 is closed. This resets the integrator 500 so that it is ready for the next acquisition cycle.
    [0058] The digital sensor values obtained can then be analyzed using the processor described above, as shown in Figures 6a and 6b. In Figure 6a, the difference 605 between the two low-energy sensors LE1 and LE2, is analyzed as a function of the transmitted X-ray beam intensity 610. In both significantly low and significantly high attenuation regions, where there is no information or where the object is thick and there is no transmission, respectively, the difference between the two sensors is small, but at intermediate intensities, the difference increases to render the dependence on specific material. Two or more thresholds as a function of intensity can be derived to allow materials to be segmented, for example, in organic (Low-Z) and inorganic (High-Z) types, 615 and 620, respectively. Since this method is based on differential X-ray absorption, through the photoelectric effect, the technique does not provide a significant discrimination result in attenuation equivalent for a steel thickness of more than about 20 millimeters for an energy of about 180 keV or 40 mm for an energy of about 1 MeV.
    [0059] As shown in Figure 6b, using the processor to determine the Compton rate for photoelectric signals provides discrimination of materials over a wide range of object attenuations and is suitable for operation in greater material thickness. Thus in Figure 6b, the difference 635 between the high energy sensor HE and the sum of the two low energy sensors LE1 and LE2 ie HE- (LE1 + LE2) is analyzed as a function of the X-ray beam intensity. transmitted 640. Combining the two effects provides a significant improvement over the use of only two low energy sensors (LE1 and LE2) or a single low energy sensor (LE1 and LE2) and a single high energy sensor (HE).
    [0060] Using the separately obtained backscatter X-ray signals, an alternative material analysis can be performed. Here, the Compton interaction of an X-ray with an electron resulted in incoherent diffusion in which the diffused X-ray has less energy than the incident X-ray. The ability of a material to diffuse is dominated by its atomic number (which is approximately proportional to the density for solid materials) - the higher the density or atomic number, the better it is in dispersion. However, dense materials are also very good at absorbing X-rays compared to low density materials. For this reason, low density materials tend to result in a stronger backscatter signal than high density materials. Such a backscatter signal can be used advantageously in a security inspection process.
    [0061] It should be noted that a signal from an X-ray source falls as the square inverse of the distance from the source and, therefore, becomes weaker the further away it is from the object, with the same effect being true radiation diffused from the object. In addition, the low-energy backscattered signal is strongly absorbed by high-density materials, such as steel, which means that this is a good technique for analyzing the steel floor in a car or similar small vehicle where you are interested in locating regions of low density material.
    [0062] Figure 7 is an illustration of a modality of a sensor that is capable of collecting information from backscattered radiation and generating a backscattering image of a region. 705 X-ray source generates a thin pencil beam of radiation that, from within the base platform, sweeps quickly from left to right over the two detector regions 710. The X-ray beam scans the field of view of the object to be inspected typically over a period of time of much less than a second and generally ranging from 5ms to 100ms. As the beam scans the object under inspection, the 710 X-ray backscatter detectors receive the broadcast signal from the point of interaction adjacent to the primary X-ray beam with the object under inspection. The strength of the backscatter signal is dependent on the density of that region of the object. By reading the time synchronization of the detector element with the position of the primary beam location, a one-dimensional backscatter image can be obtained. Knowing the speed at which the vehicle moves beyond the sensor allows a two-dimensional image to be recreated from the set of one-dimensional image sections.
    [0063] In one embodiment, the detectors are advantageously formed using a wide area scintillation detector where the light generated from X-ray is reflected into a large photo-sensing area such as a photomultiplier tube. An alternative embodiment may comprise a gas ionization chamber with a dispersion field to accelerate the collection of ions and electron signal currents.
    [0064] Figure 8 is a representative cross-section of an X-ray source that can be used with the present invention. Radiation source 800, with an extended anode 805, is shown by which anode 805 operates at ground potential with cathode 810 at a high negative voltage. It will be apparent to a person skilled in the art that alternative configurations with a grounded cathode and differential systems with a cathode at the negative potential and the anode at the positive potential are also possible. The X-ray source is protected by suitable materials, such as tungsten and lead, to prevent unwanted radiation from the X-ray tube to reach the object under inspection.
    [0065] An electric motor 815 and a gearbox 820 drive a collimator 825 comprising a solid tungsten block or a combined tungsten / lead / steel assembly forming one or more predetermined voids, spaces, or holes 830 that allow the radiation is emitted in a pencil beam shape in a direction perpendicular to the axis of rotation of the collimator 825. Two such collimator holes 830 are shown diametrically opposed in Figure 8. A high voltage connection 840 provides a point for the electrical connection with the X-ray tube in such a way that the high voltage power supply can be mounted remotely away from the X-ray inspection area.
    [0066] During operation, the axis of rotation of the collimator is in the direction of movement of the object under inspection in such a way that the primary X-ray beam sweeps in a direction perpendicular to the movement of the object under inspection. As shown in Figure 9, the X-ray beam 905 emerges from the source assembly 906 in a first direction and, at the point of intersection 907 of the primary beam 905 with the object to be inspected 910, generates backscattered radiation 912, which interacts with the adjacent X-ray detector 915.
    [0067] As described above, the intensity of the primary beam averaged over an area is dependent on the distance from that measurement point from the source of the source. For this reason, the signal received at the periphery of the scanning zone will be less intense than that received closer to the center of the inspection zone for an identical broadcast surface. To solve this problem, as shown in Figure 10a, in an embodiment of the present invention, the rotary collimator section type pencil is replaced with a slot collimation section 1005. A second collimation opening 1010 is then placed adjacent to the rotary collimator and parallel to the inspection surface. Secondary collimator 1010 is narrow in the center of inspection area 1015 (directly above rotary slot collimator 1005) and extends outwardly, a distance from the rotary slot collimator. This provides a small irradiation area 1020 at the center of the inspection region when the intensity of the primary beam is high and greater irradiation at the periphery of the inspection region when the intensity of the primary beam is lower. This preserves the dynamic range of the signal and makes it easier for both to collect the data with good signal-to-noise ratio and to reconstruct the individual scan line object density.
    [0068] In order to minimize interference between the backscatter imaging component and the transmission X-ray imaging system, it is advantageous to synchronize the operation of the two systems. For a rotating backscatter collimator with two openings, each located substantially opposite the other (that is, one rotated 180 degrees from the other), there are times in time when no collimator is emitting a beam on the object. This occurs with the collimator at both 0 degrees and 180 degrees in relation to the scanning plane.
    [0069] Therefore, as shown in Figure 10b, it is preferred to activate a time-pulsed X-ray source T1-N 1030 to generate a corresponding line from the transmission X-ray image, when the collimator is not emitting a backscatter beam to the object, shown as T'1-N 1040 times, thus avoiding interference with the backscatter detector. In one embodiment, for a pulsed X-ray source at 100 Hz, the backscatter image collimator needs to operate at 50 revolutions per second or 300 RPM. By placing a phase lock loop or equivalent feedback circuit between the collimator motor controller and the X-ray transmission source controller, it is possible to adjust the frequency of the collimator and X-ray source to take into account the variation in the speed of the object under inspection as it passes through the X-ray imaging system.
    [0070] As shown in Figures 11a, 11b, 11c and 11d in another embodiment of the present invention, the mechanical sweep assembly can optionally be integrated with a trailer to allow towing the equipment behind a vehicle. Figure 11a shows the 1105a system in a first configuration, deployed and ready for use, where the transport trailer 1110a is folded up on the side of the inspection system and vehicle ramps 1115a are in an open position and ready to be driven- about. When it is time to tidy up the equipment, the detector arrays are folded down and the vehicle ramps 1115b are folded up, as shown in Figure 11b such that the system is in a second configuration. As shown in Figure 11c, in a third configuration, trailer 1110c is lowered, lifting one end of the 1120C imaging equipment. As shown in Figure 11d, a winch or other mechanism is then used to pull the 1105d X-ray system to the trailer ready for transport, in a fourth configuration. To implement the system, the process described above is implemented in reverse. Advantageously, the vehicle, which is used to tow the trailer is provided with image inspection computers, which one or more operators can use to analyze the images and thus divert and stop the vehicles for further research as needed and which comprises the memory above mentioned and processors used to process incoming backscatter transmission data signals.
    [0071] Figure 12 represents another embodiment of the present invention in which a four-sided backscatter detector 1205 is mounted around the periphery of the scanning tunnel. Each detector panel is similar to the sensor described with reference to Figures 7, 8, 9 and 10, but now a four-sided backscatter image can also be generated. Advantageously, the backscatter detectors are mounted on the same frame as the transmission X-ray system in such a way that simultaneous backscatter and transmission image data can be acquired. This allows overlapping of transmission and backscatter X-ray images by proper image manipulation. In this embodiment, the backscatter detectors, and not a backscatter X-ray source, are integrated into one or more of the first side 106, second side 107, and upper side 108. Alternatively, the backscatter detectors, and not a source X-ray backscatters, can be integrated into all three of the first side 106, second side 107, and upper side 108. Alternatively, backscatter detectors with a backscatter X-ray source can be integrated one or more of the first side 106, second side 107, and upper side 108.
    [0072] Figures 13a, 13b, and 13c show other modalities of the X-ray system of the present invention with alternating transmission X-ray image geometries. Figure 13a shows the X-ray source 1305a in a "sniper" configuration, while Figure 13b shows a combination or dual display system that includes both "sniper" 1305b and "sniper side" 1310b. Figure 13c shows a dual display system, with both sniper 1305c, and sniper side 1310c, further comprising a four-sided backscatter system, with a backscatter source and backscatter detectors integrated into the base of the 1320c system and detectors backscatter, together with transmission detectors, integrated on each of the remaining three sides 1325c. It should be evident to those with common skills in the art that other configurations can be derived based on this disclosure.
    [0073] Figure 14 is an illustration of an embodiment of the present invention in which the system further comprises at least one, and preferably a combination of two vehicle presence detection sensors 1405 and 1410, to the right and left, respectively, of the gantry. main 1401. Sensor 1405 is used to switch on the X-ray beam when vehicles approach. This is the rightmost sensor when the vehicle approaches the right, as shown in the diagram. Sensor 1410 (the leftmost sensor in the figure) is used to connect the X-ray beam once the vehicle has passed through the image plane. In one embodiment, an additional sensor can be used to measure the vehicle's speed as it passes through the sensor. The vehicle speed can be used to modulate the collimator's rotation speed and source pulse rate to ensure that good image quality is maintained regardless of the vehicle speed. This also allows a constant dose per unit length of the vehicle, on inspection to be delivered which helps to ensure a known and safe dose for the driver and other occupants of the vehicle, during X-ray screening.
    [0074] Figure 15 shows a composite image that overlays the 1505 X-ray backscatter signal from the bottom of the vehicle under inspection to be correlated with an optical image 1510 of the same vehicle that is acquired through a suitable optical system, when time the X-ray image is acquired.
    [0075] Figure 16 shows an exemplary mechanism by which the optical image can be generated by taking an image signal from a mirror 1605 that rotates with the X-ray collimator by means of one or more optical filters 1610 for one or more detectors of photographs 1615. This configuration ensures that the optical image is captured at a known time in relation to the generation of a transmission image.
    [0076] Although what is currently considered to be a preferred embodiment of the present invention has been illustrated and described, it will be understood by those skilled in the art that various changes and modifications can be made, and equivalents can be replaced by elements of the same without departing from the true scope of the invention. In addition, many modifications can be made to adapt a particular situation or material to the teachings of the invention without departing from its central scope. Therefore, it is intended that this invention is not limited to the particular modalities disclosed as the best mode contemplated for carrying out the invention, but that the invention includes all modalities that fall within the scope of the appended claims.
    权利要求:
    Claims (21)
    [0001]
    Scanning system for cargo inspection, characterized by the fact that it comprises: a portal defining an inspection area, said portal comprising a first vertical side, a second vertical side, an upper horizontal side, and a horizontal base defined by a ramp adapted to be driven over by a vehicle; a first X-ray source arranged on at least one of the first vertical side, second vertical side or upper horizontal side for the generation of an X-ray beam for the inspection area for the vehicle; a first set of transmission detectors arranged inside the portal to receive the X-rays transmitted through the vehicle; a second X-ray source disposed within the ramp of said portal for the generation of an X-ray beam for the lower portion of the vehicle, and a second set of detectors disposed inside the ramp of said portal for the reception of X-rays that are backscattered from the vehicle.
    [0002]
    System according to claim 1, characterized by the fact that said first X-ray source is a high energy source having an energy ranging from 100 kVp to 2 mV.
    [0003]
    System according to claim 1, characterized by the fact that said second X-ray source is a low energy source having an energy ranging from 60 kVp to 250 kVp.
    [0004]
    System according to claim 1, characterized by the fact that it further comprises a controller, in which said controller is adapted to activate the first X-ray source only when the second X-ray source is inactive.
    [0005]
    System according to claim 1, characterized by the fact that said system can be retracted.
    [0006]
    System according to claim 5, characterized in that said ramp comprises an articulated base platform for a first angled surface and a second angled surface and in which, when said system is retracted, the first angled and second surface angled surface are rotated upwards.
    [0007]
    System according to claim 1, characterized in that said upper horizontal side is connected to said first vertical side at a first end and to said second vertical side at a second end, and in which the first source of radius X is arranged in a midpoint shape between said first end and said second end.
    [0008]
    System according to claim 1 characterized by the fact that it also comprises a primary rotating collimator placed adjacent to said second X-ray source, and a secondary static collimator placed adjacent to said rotating collimator and parallel to the inspection surface, in which said secondary collimator is adapted to generate a first irradiation area in the center of the inspection area and a second irradiation area at a periphery of the inspection area and wherein said second irradiation area is larger than the first irradiation area .
    [0009]
    System according to claim 1, characterized by the fact that it also comprises backscatter detectors on at least one of said first vertical side, said second vertical side, and said upper horizontal side.
    [0010]
    System according to claim 9, characterized by the fact that a backscatter X-ray source is not arranged with said backscatter detectors on at least one of said first vertical side, second vertical side, and said upper horizontal side .
    [0011]
    Method for inspecting a vehicle, characterized by the fact that it comprises: providing a portal defining an inspection zone, said portal comprising a first vertical side, a second vertical side, an upper horizontal side, and a horizontal base defined by a ramp adapted to be driven over by a vehicle, signal a vehicle to go over the ramp, radiate a vehicle with X-ray from a first source arranged on one side of the portal, detect the X-rays transmitted through the vehicle, using transmission detectors placed inside the portal, to produce a first representative signal of the vehicle and its contents, irradiate the lower portion of the vehicle with X-ray from a second source disposed within the ramp, detecting back-spread X-rays from the vehicle, using backscatter detectors arranged inside the ramp, to produce a second representative signal of the vehicle and its contents, and correlating said first output signal and said second output signal to produce a visual image of the vehicle and its contents.
    [0012]
    Method according to claim 11, characterized by the fact that said first X-ray source is a high energy source having an energy ranging from 100 kVp to 2 mV.
    [0013]
    Method according to claim 11, characterized in that said second X-ray source is a low energy source having an energy ranging from 60 kVp to 250 kVp.
    [0014]
    Method according to claim 11, characterized in that said first X-ray source is operated when said second X-ray source is inactive.
    [0015]
    Scanning system to inspect a vehicle, characterized by the fact that it comprises: a portal defining an inspection zone, said portal comprising a first vertical side and a second vertical side spaced from each other and each having an upper side; a third side connecting said two upper sides; a ramp adapted to be driven over by a vehicle; an X-ray source arranged on one side of the portal to generate an X-ray beam for the inspection area; a first set of detectors arranged inside the portal for the reception of X-rays transmitted through the vehicle; a second set of detectors disposed inside the ramp and the first, second and third sides of said portal for receiving back-broadcast X-rays from the vehicle; and an image processor for receiving output signals from said first and second set of detectors and superimposing said output signals on top of a visual image of the vehicle and its contents.
    [0016]
    System according to claim 15, characterized by the fact that said first set of detectors is arranged on at least two of the same sides of the portal as the second set of detectors.
    [0017]
    System according to claim 15, characterized in that said first set of detectors comprises a first detector and a second detector adapted to measure an X-ray energy component transmitted through the vehicle in a range from 0 keV to 50 keV and 20 keV at 200 keV, respectively, and a third detector to measure an X-ray energy component transmitted through the vehicle in a range of 100 keV to 2 MeV.
    [0018]
    System according to claim 17, characterized by the fact that said three detectors are in a stacked configuration.
    [0019]
    System according to claim 17, characterized by the fact that a difference between an output from the third detector and a sum of outputs from the first and second detectors is used to achieve material discrimination.
    [0020]
    System, according to claim 15, characterized by the fact that it also comprises a sensor to measure the speed of the vehicle as it passes through the portal.
    [0021]
    System according to claim 20, characterized by the fact that it further comprises a controller in which said controller is in data communication with the sensor and receives the vehicle speed and in which said controller is adapted to modulate a rate of pulse from the X-ray source to achieve a substantially constant dose per unit length of the vehicle under speed-based inspection.
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    法律状态:
    2019-01-15| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-07-23| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-04-22| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2020-09-24| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 24/09/2020, OBSERVADAS AS CONDICOES LEGAIS. |
    2021-06-22| B16C| Correction of notification of the grant|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 13/07/2010, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO |
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