Abstract: An X-ray emission device having an X-ray tube and a protective enclosure filled with an electrically insulating liquid in which the X-ray tube is placed. The device includes at least one chamber connected to the protective enclosure that traps and purges gas bubbles contained or dissolved in the liquid filling the protective enclosure.

Abstract: A heat exchanger removes heat generated by a miniaturized x-ray source to help remove heat at the site of x-ray generation.

Abstract: A cooling oil circuit (D) circulates cooling oil over an x-ray tube absorbing its waste heat. A refrigeration circuit (E) then cools the cooling oil. A heat buffer (52) absorbing peak heat loads from the cooling fluid when the x-ray tube is generating x-rays. Valves (58, 60) regulate a relative amount of cooling oil entering the heat buffer to increase heat transfer efficiency. The heat buffer enables the system to handle peak heat loads with a smaller, more condensed refrigeration system, by absorbing heat during operation of the x-ray tube and releasing heat between operations.

Abstract: An X-ray computed tomography apparatus including a rotor rotated in a predetermined direction, an X-ray tube unit mounted on the rotor, an X-ray detector opposed to the X-ray tube unit to detect X-ray transmitted through a subject, and a radiator unit mounted on the rotor. The radiator unit includes a tubed casing, a radiator engaged with a frontal opening of the casing in an orientation in which the radiator is subjected to the air moved by rotation of the rotor at a substantial front face thereof, a circulating system configured to circulate a fluid between the X-ray tube unit and the radiator, and a radiator air exit opened at the rear of the casing. The radiator unit further includes a switch for opening and closing the radiator air exit.

Abstract: The present invention is directed to a radiographic apparatus that utilizes a single integral housing for providing an evacuated envelope for an anode and cathode assembly. The integral housing provides sufficient radiation blocking and heat transfer characteristics such that an additional external housing is not required. The integral housing is air cooled, and thus does not utilize any coolant. In addition, the integral housing is insulated with a potting material, which electrically insulates the integral housing and its components, and also limits the amount of noise emitted from the housing during operation. In an alternative embodiment, enhanced thermal and electrically insulating properties are achieved through the use of a potting material disposed in selected areas of the tube interior. The potting material cooperates with optimized airflow through the tube assembly to effectively and continuously remove heat therefrom.

Abstract: A CT scanner comprises a beryllium window mounted on an x-ray insert, a cooling fluid circulation line, and a cooling fluid return line. A plurality of fins are mounted in the cooling fluid circulation line. The fluid circulation line is in fluid communication with one of an anode side cavity and a cathode side cavity and in fluid communication with a heat exchanger. The fluid return line is in fluid communication with the heat exchanger and in fluid communication with the other one of the anode side cavity and the cathode side cavity. A pump means circulates the cooling fluid through the heat exchanger, the suction and return lines, and the x-ray tube housing assembly.

Abstract: A system and method for improving cooling of a heat-generating component in a closed-loop cooling system is shown. The system comprises a venturi having a throat which is coupled to an expansion tank that is exposed to atmospheric pressure in the embodiment being described. The venturi, when used with a pressure switch, can operate to determine a flow rate which can be used to generate a signal which in turn is used to activate or deactivate one or more of the components, such as the heat-generating component, in the system. Advantageously, the design of the embodiment described has a convenient system which utilizes a pressure switch, thereby eliminating the need for a differential pressure switch of the type used in the past.

Abstract: A CT scanner comprises an x-ray window mounted on an x-ray tube, a cooling fluid circulation line, and a cooling fluid return line. A cold-plate is operatively mounted on the x-ray tube around the x-ray window. The cold plate includes an elongated shell and corrugated fins for rapidly removing heat from the x-ray window. The circulation line is in fluid communication with an inlet of the cold-plate, a cooling fluid reservoir defined between the x-ray tube and a surrounding housing, and a heat exchanger. The return line is in fluid communication with an outlet of the cold-plate, the cooling fluid reservoir, and the heat exchanger. A pump circulates the cooling fluid through the heat exchanger, the suction and return lines, the cold-plate, and the x-ray tube housing.

Abstract: An x-ray generating system has an x-ray source arranged in a coolant-filled housing, and a phase change store which contains a phase change material disposed in the coolant in the housing.

Abstract: A computed tomography system has a gantry rotating around a patient acceptance space in a stationary gantry housing, the gantry carrying an x-ray radiator connected to a cooling device. The x-ray tube is a directly cooled rotating bulb tube whose coolant serves as an intermediate heat store and which is cooled in standstill periods of the gantry by a likewise co-rotating heat exchanger via a coolant pump.

Abstract: An x-ray technique-based nonintrusive inspection apparatus is provided which is capable of inspecting 600 containers an hour which is small, and which is easily maintainable. Features of the apparatus include “radiation locking” with “active curtains”, “continuous scanning” utilizing an x-ray line scanner subsystem and a CT scanner subsystem, good structural integrity, radiation containment in a self-shielding manner, an easily maintainable driving arrangement, shielding curtains that can be raised and lowered quickly, a container jam release mechanism, and efficient air conditioning.

Abstract: The invention relates to an X-ray examination apparatus in which the X-ray detector 1 and the X-ray source 2 are subject to keeping the temperature constant and to cooling by way of a common cooling circuit. To this end, a cooling medium of constant temperature is applied to the X-ray detector 1 in order to make the X-ray detector 1 operate at uniform ambient temperatures. The temperature of the cooling medium, thus increased a first time, still suffices to perform cooling of the X-ray source 2. Consequently, the heated cooling medium, after application to the X-ray detector 1, is applied to the X-ray source 2 where a second exchange of heat takes place, so that at the same time the X-ray source 2 is cooled without utilizing an additional cooling circuit.

Abstract: A rotating bulb x-ray radiator has an x-ray tube accepted in a housing filled with a coolant, the x-ray tube being torsionally connected to the housing and being mounted so as to be rotatable together therewith. The housing is at least partially formed of a material that is highly attenuating for x-rays.

Abstract: The present invention is directed to a radiographic apparatus that utilizes a single integral housing for providing an evacuated envelope for an anode and cathode assembly. The integral housing provides sufficient radiation blocking and heat transfer characteristics such that an additional external housing is not required. The integral housing is air cooled, and thus does not utilize any coolant. In addition, the integral housing is insulated with a dielectric gel material, which electrically insulates the integral housing and its components, and also limits the amount of noise emitted from the housing during operation.

Abstract: The present invention teaches methods and apparatus for extending the life of an x-ray tube. An x-ray tube typically contains an insert for generating x-rays. The insert is housed in a housing wherein an insulating fluid circulates around the insert in the housing to provide thermal and electrical insulation. The present invention includes methods and apparatus for removing water from insulating oil. One embodiment of the invention includes a processor containing a coalescing element for removing water as a vapor from the oil. Other embodiments include methods and devices for drying the interior of the housing. Another embodiment of the invention includes a kit containing a processor having a coalescing element for removing water from the insulating oil. The portable kit allows the invention to be practiced on x-ray tubes maintained in gantry supports of x-ray machines, such as CT scanners.

Abstract: In an arrangement for cooling an X-ray tube mounted on the gantry of a CT system, a path of flow is established by means of conduits or the like for circulating a cooling fluid between the tube and a heat exchanger. As fluid passes through the heat exchanger, a stream of air is applied to the path of flow, by means of a radial fan, to carry heat away from the fluid. The axis of the fan is maintained in parallel relationship with the axis of the gantry, to prevent gyroscopic loading of the fan as the fan rotates about the gantry axis with the gantry. The fan comprises a device for exhausting air heated by the exchange process radially, with respect to the fan axis, to minimize fan-generated acoustic noise while maintaining good thermal performance. Fan support structure lying in the path of the exhausted air is selectively shaped to reduce air flow turbulence, and to thereby further reduce fan noise.

Abstract: An X-ray CT system includes a fixed frame portion and a rotating frame portion. Being provided with X-ray tubes, the rotating frame portion is arranged so as to rotate with respect to the fixed frame portion. Vane members for feeding air are secured on the rotating frame portion. In operation, with the rotation of the vane members together with the rotating frame portion, cool air is introduced into the rotating frame portion. Consequently, heated instruments, such as the X-ray tubes, in the rotating frame can be cooled down effectively.

Abstract: A method and system for extending the service life of an x-ray tube wherein the coolant fluid which is circulated through a closed circulation system to remove heat generated by the x-ray tube and provide electrical insulation between anode connections and ground (and/or cathode connections) is regularly filtered and/or changed based on predetermined criteria. Provided for performing the filtering and/or changing is a cart which, preferably, is mobile, portable or otherwise easy and convenient to operate. The cart includes a new oil reservoir, an old oil container, various valves and a bidirectional pump for performing various functions. For example, the cart allows a technician or other skilled individual to connect the cart to a source of new oil for the purpose of filling its new oil reservoir container, this being known as the FILL mode.

Abstract: A CT scanner includes a stationary gantry (C) having an examination region (12) centrally therein. A rotating frame or gantry (C) which is mounted for rotation about the examination region carries an x-ray tube assembly (B), a liquid-to-liquid heat exchanger (34), and a liquid-to-air heat exchanger (48) around a peripheral edge thereof. A first closed loop (30) carries a first cooling fluid, particularly oil, between a housing (22) which surrounds an x-ray tube (68) and the liquid-to-liquid heat exchanger to remove heat from the x-ray tube. A second closed loop (40) conveys a second cooling fluid, particularly water, between the liquid-to-liquid heat exchanger and the peripheral liquid-to-air heat exchanger. The second closed loop includes a reservoir (44) for storing a substantial volume of water such that a significant portion of the heat generated during an x-ray examination can be stored by the water in the reservoir.

Abstract: A method and system for extending the service life of an x-ray tube wherein the coolant fluid which is circulated through a closed circulation system to remove heat generated by the x-ray tube and provide electrical insulation between anode connections and ground (and/or cathode connections) is regularly filtered and/or changed based on predetermined criteria. In addition to the fluid change, an on-line fluoroscopy is also regularly performed based on a separate set of predetermined criteria. Provided for performing the filtering and/or changing is a cart which, preferably, is mobile, portable or otherwise easy and convenient to operate. The cart includes a new oil reservoir, an old oil container, various valves and a bidirectional pump for performing various functions. For example, the cart allows a technician or other skilled individual to connect the cart to a source of new oil for the purpose of filling its new oil reservoir container, this being known as the FILL mode.

Abstract: A high-voltage plug for an X-ray tube plugs onto a high-voltage terminal provided at the vacuum housing of the X-ray tube. The high-voltage plug contains a cooling channel for a coolant. An improved are over protection results by use of the coolant.

Abstract: Temperature control of solid state detectors carried on the rotating gantry of computed tomography equipment is impractical for very detailed images. The temperatures of all of the detectors in the array can be equalized, however, by closely coupling them to a thermally massive object and isolating this combination from the environment. Significant thermal gradients are thereby removed from the array, and time is removed as a calibrating factor. The detectors are mounted on a common heat sink which provides the thermal mass, and the heat sink is covered with insulation and attached to the gantry by thermally isolating mounts, such as thin flexible stainless steel plates.

Abstract: A method and system for extending the service life of an x-ray tube wherein the coolant fluid which is circulated through a closed circulation system to remove heat generated by the x-ray tube and provide electrical insulation between anode connections and ground (and/or cathode connections) is regularly changed based on predetermined criteria. In addition to the fluid change, an on-line fluoroscopy is also regularly performed based on a separate set of predetermined criteria.

Abstract: A radiogenic unit comprising an X-ray tube with fixed anode made of copper and its circuit for high-voltage supply in single-pole mode, these elements being placed in two parts that are imperviously sealed against fixed against X-rays, secured to each other in a hermetically sealed way. The first part, made of an electrically insulating material, has cavities for the housing of the X-ray tube and its supply circuit. The second part, made of material with high thermal conductivity, comprises a cavity for the housing of the tube, the anode of which is connected to a thermal and electrical frame. It can be applied particularly to radiology instruments.

Abstract: The invention is directed to a method for operating an x-ray installation having an x-ray radiator, which comprises an x-ray tube accepted in a housing filled with an electrically insulating liquid. The electrically insulating liquid is thereby degasified at intervals in order to prevent gases arising as a consequence of the decomposition of the electrically insulating liquid caused by the generated x-ray radiation from deteriorating the high-voltage strength of the x-ray radiator.

Abstract: A CT scanner has an x-ray tube (B) which is carried by a rotating gantry portion around a patient receiving region (12). A large diameter, annular radiator (30) is connected to the rotating gantry for rotation with the x-ray tube. A cooling oil is circulated around the x-ray tube and through passages (32, 74, 100) of the rotating radiator. An annular stationary member is mounted to a stationary gantry portion (A) of the CT scanner. In the embodiment of FIGS. 2 and 3, the stationary member is an annular tube (36) which substantially surrounds the rotating radiator except for an annular access aperture (38). Spray jets (40) spray the rotating radiator with water which is drained (42), circulated to a remote heat exchange or cooling apparatus (D), and recirculated to the spray nozzles. Baffles (52, 54), gutters (58), lip and baffle arrangements (54, 56), and the like, inhibit the sprayed water from escaping from the tube (36). In the embodiment of FIG. 4, the water is sprayed on a wick member (76).

Abstract: A safety device for an X-ray unit comprises an X-ray tube protected by a casing and cooled by a fluid circulating between the tube and the casing. This device is aimed at preventing any excess pressure of the cooling fluid in the casing. It comprises a rigid, hermetically sealed and vacuum-tight cavity connected to the circuit of the fluid by a hydraulic connector with a high flow rate, designed to open mechanically and automatically under the effect of the fluid, by a pressure that exceeds a predetermined threshold.

Abstract: An x-ray radiator has a protective housing filled with liquid in which an x-ray tube is contained. Due to the interaction of the x-rays passing through the liquid from the x-ray tube out of the housing, gas is created in solution in the liquid. A degasifier is therefore provided within the protective housing, which includes a gas volume, a space accepting the liquid to be degasified, a liquid-impermeable wall separating the space from the gas volume, and which generates, in the space which accepts the liquid to be degasified, a partial gas pressure which is lower than the partial gas pressure of the gas to be eliminated.

Abstract: A rotary anode x-ray tube includes a vacuum vessel in which a cathode, an anode target, a connecting rod, a rotor, bearings, and a heat conducting plate are arranged. The cathode electrode emits electrons. The anode target generates x-rays when electrons emitted from the cathode electrode collide with the target. The connecting rod supports the anode target. The connecting rod is constituted by a rod member consisting of a pulverized sintered material. The rotor is mounted on the connecting rod. The anode target is rotatably supported by the bearings. The heat conducting plate is arranged between the anode target and the rotor. A heat conducting plate made of a material having excellent heat conduction characteristics can be arranged between the anode target and the rotor. The connecting rod is manufactured by processes such as plasticization including tube spinning.

Abstract: An interstitial X-ray needle includes an elongated X-ray tube coupled to an electron emitter at one end of the tube, with a converter element being disposed at a tip of the other end of the tube for converting emitted electrons into X-ray; a solenoid coil wound around the tube for providing a magnetic field that confines the emitted electrons within a narrow beam; an elongated outer casing enclosing the tube and coil; and a pipe coaxially disposed between the casing and the tube for defining an inner annular flow chamber between the tip of the tube and a coolant inlet in the casing and an outer annular flow chamber between the tip of the tube and a coolant outlet in the casing.

Abstract: An X-ray stand with two hollow arms for supporting an X-ray tube and an X-ray receptor contains within one hollow arm a grounded anode X-ray tube and a non-inductive Cockcroft-Walton voltage multiplier power supply also grounded at one end to the support arm. The hollow arm forms a chamber filled with insulating fluid surrounding both the X-ray tube and its voltage multiplier. The voltage multiplier and X-ray tube plug together physically and electrically within the oil filled arm.

Abstract: A coolant oil from an x-ray tube (14) is circulated through a heat exchanger (18) to reduce its temperature. More specifically, at least one hot coolant fluid receiving aperture (30) is defined adajcent an end of a suction tube 32) in an upper most portion of a horn portion (16) surrounding a cathode termination assembly. Bubblers (42) of gas in the fluid which could be ionized by electrical fields inside the x-ray tube housing causing x-ray tube current irregularities and corresponding x-ray tube output irregularities are drawn into the suction tube aperture. A debubbler (38) removes bubbles from the cooled coolant fluid before it is returned into an anode horn portion (20) of the x-ray tube. Alternately, the bubbles may be reabsorbed, dissolved, or homogenized by the action of the heat exchanger and pump. The coolant fluid passes through a central portion (24) of the x-ray tube absorbing heat and back to the cathode horn portion.

Abstract: There is disclosed a unitized rotating shaft assembly comprising an outer alignment sleeve within which are mounted a rotating ferrofluid seal, a first bearing, a stator a second bearing and a rotating union; there being a first follow shaft affixed to the inner races of the first and second bearing, the hollow shaft having stators mounted opposing the rotor and there being a second hollow shaft concentric with the first hollow shaft to provide separate conduits for the input and discharge of coolant.

Abstract: An x-ray radiator has an x-ray tube disposed in a coolant-filled housing formed by a tank and an insertable closure for the tank. The x-ray tube is held in a tube carrier, which is mounted to the insertable closure so that the position of the tube carrier, and thus of the x-ray tube, can be adjusted relative to the insertable closure.

Abstract: A patient receiving region (12) is defined within a stationary CT scanner frame (A). An x-ray tube (B) is mounted on a rotating frame portion (40) for rotation about the patient receiving region on an annular bearing (44, 46, 48). A fluidic slip ring (60) is mounted between the rotating and stationary frames adjacent the bearing for conveying cooling fluid between the x-ray tube and a stationarily mounted, preferably off-site, chiller (D). The fluidic slip ring enables large amounts of heat to be removed from the x-ray tube to maintain the x-ray tube at proper operating temperatures without overheating the interior of the CT scanner, the CT scanner room, or the like.

Abstract: The disclosure concerns X-ray tubes. To obtain greater temperature stability of an X-ray tube, a substance is placed in the circulation space of the cooling fluid of the tube. The latent heat of fusion of this substance is used so that it melts during the examination stage in absorbing heat, and gets solidified during the resting stage. The disclosure is applicable to X-ray tubes.

Abstract: Cooling oil for an X-ray tube head assembly is contained within a resilient elastomeric envelope together with a high voltage assembly.

Abstract: A peripheral cooling duct (36) is mounted on a removable front door panel (26) of a CT scanner (10). A pressure source (74) supplies ambient air at elevated pressure through air inlet means (70) defined by an inner wall (78) of the cooling duct. Concentric flanges (58, 60) extending inward toward the inner region (76) of the CT scanner define a slit-like circular nozzle opening (56). Air is directed from the cooling duct through the nozzle opening across radiation detectors (20) for cooling the detectors and other features of the CT scanner during scanner operation.

Abstract: An X-ray tube generally comprises an evacuated tube envelope fabricated primarily of metal and having first and second end walls and a cylindrical sidewall, and encloses a rotating anode with its target surface facing the second end wall. A heat transfer sleeve extends from the first end wall past the anode to receive heat from the anode and transfer it to the end wall for dispersal. A heat transfer cross plate at the end of the sleeve further encloses the anode to receive and transfer heat. The tube envelope is mounted in a cylindrical tube housing with the first end wall in contact with a finned mounting plate for dissipating heat. The surface of the tube envelope remains sufficiently cool to apply a layer of lead, whereby the tube is compact. The anode and cathode electrical feeds are through the second end wall. The electrical feeds have angled terminations with lead on them.

Abstract: An X-ray generator includes a vacuum vessel; a cathode disposed in the vacuum vessel for emitting an electron beam; a plurality of stators constituting an electric motor and disposed within the vacuum vessel for generating rotating magnetic fields; a drum-shaped anode adapted to rotate upon reception of the rotating magnetic fields generated from the stators and radiate an X-ray upon reception of the electron beam emitted from the cathode, the drum-shaped anode having a circumferentially extending narrow groove formed at the position where the electron beam from the cathode is focused; a plurality of rotary fins mounted on the drum-shaped anode for dissipating the heat generated in the groove upon radiation of an X-ray; and a plurality of fixed fins mounted within the vacuum vessel in opposed relation to the rotary fins and adapted to receive the heat transferred from the rotary fins and dissipate the heat to the outside of the vacuum vessel.

Abstract: A computer tomography apparatus has a stationary part in which a live ring is rotatably seated, the live ring carrying heat generating components such as an x-ray source and a radiation detector, which are disposed on opposite sides of an opening in which an examination subject is received. The stationary part and the live ring limit a sealed annular channel therebetween, the channel having at least one inlet opening and at least one outlet opening for a gaseous coolant. A conduit, which also contains a circulating coolant, has various portions disposed to carry away heat from the heat generating components, and another portion disposed within the annular channel so that the heat can be removed therefrom by the gaseous coolant.

Abstract: An x-ray source having a cathode and a disc-shaped anode with a peripheral surface at constant radius from the anode axis opposed to the cathode. The anode has stub axle sections rotatably carried in heat conducting bearing plates which are mounted by thermoelectric coolers to bellows which normally bias the bearing plates to a retracted position spaced from opposing anode side faces. The bellows cooperate with the x-ray source mounting structure for forming closed passages for heat transport fluid. Flow of such fluid under pressure expands the bellows and brings the bearing plates into heat conducting contact with the anode side faces. A worm gear is mounted on a shaft and engages serrations in the anode periphery for rotating the anode when flow of coolant is terminated between x-ray emission events.

Abstract: A tomographic apparatus has a rotatable part mounted for rotation in a track of a stationary part. The apparatus has a radiation field generating element which requires cooling, and has a coolant circulator for that purpose. As a further part of the cooling system, the coolant is circulated around the exterior of the rotatable part in the vicinity of the track, and a number of cooling fins in heat-transferring communication with the coolant project into the track for dissipating heat from the coolant. An additional coolant may be circulated within the track for assisting in removal of heat from the cooling fins. The rotatable part may be further provided with a transmitting antenna, and the stationary part provided with a receiving antenna, for transmitting signals between those parts relating to examination of a subject.

Abstract: A unitary portable X-ray apparatus including a high voltage section, an X-ray generator section and a cooled anode section. Preferably the sections are cylindrical and arranged end to end with at least the X-ray section being separated from the high voltage section by generally conically shaped bushings extending into the X-ray generator section. A cathode mounted in the extending end of the bushings and connected to a high voltage generator in the high voltage generator section contains a filament to which an AC voltage is applied by electromagnetic induction. A shielded anode mounted in the anode section and having a target therein has an open end extending into the X-ray section for axially aligning the target with the filament. Alternatively, the outer end sections may both be high voltage sections each separated from the X-ray generator section by generally conically shaped bushings extending into the X-ray generator section.

Abstract: An X-ray apparatus comprising a casing filled with an insulating gas, a high voltage transformer in said casing, an X-ray tube mounted to said casing and connected to said transformer, an X-ray shielding member attached to the wall of said X-ray tube and defining a window through which the X-rays radially emitted by said X-ray tube are released in a predetermined direction, and means defining an X-ray path through which said X-rays released through said window of said X-ray shielding member are directed so as not to be radiated on said insulating gas, whereby a reduction of the dielectric strength is prevented and the cooling efficiency is improved.

Abstract: A completely enclosed, self-contained, air-cooled industrial X-ray machine having a housing which is also a gas-to-gas heat exchanger. The cylindrical metallic housing for the X-ray tube and power transformers is machined to provide a large plurality of narrow radial grooves with intervening narrow vanes on both the inside surface and the outside surface. The outside is covered with a thin-walled cylindrical jacket to provide a plurality of longitudinal passageways. An inside tubular sleeve provides support for the X-ray tube and is adapted to fit closely inside of the inner grooves to provide a plurality of longitudinal passageways on the inner surface. The housing is closed off and sealed with end plates and the interior is filled with a selected heat-transfer and insulating gas at a selected pressure. An internal fan provides circulation of the gas over the X-ray tube and back to the inner longitudinal passageways to the fan. An outside fan circulates room air through the outer longitudinal passageways.