A two-phase cooling system for an X-ray high-voltage generator comprises a heat sink block and a heat sink. The heat sink block spatially surrounds a cooling duct loop, wherein the cooling duct loop is at least partially filled with a working medium and is configured to act as an oscillating heat pipe. The heat sink is configured to dissipate heat from a heat source. The heat sink block includes a material including a polymer.

A soft X-ray light source, including a vacuum target chamber, a refrigeration cavity, and a nozzle. The refrigeration cavity and the nozzle are contained in the vacuum target chamber. The nozzle (36) is arranged in the refrigeration cavity. The vacuum target chamber has a t-branch tube and a multi-channel tube. The t-branch tube has a first outlet and a second outlet opposed to each other and a third outlet, wherein the first outlet is connected to a mounting plate through which a refrigerant inlet pipe, a refrigerant outlet pipe, and a working gas pipe respectively pass and are connected to the refrigeration cavity, and wherein the third outlet is connected to a vacuum extraction device. The multi-channel tube has a top opening and a bottom opening opposed to each other, wherein the top opening is connected to the second outlet, wherein a vacuum outlet is provided at the bottom opening.

A cooling system used in an X-ray generator having a cathode and anode that includes a target having a focal spot, wherein heat is generated in the anode and focal spot during operation of the X-ray generator. The system includes a heat transfer element attached to the anode wherein the heat transfer element includes a plurality of fin elements that transfer heat from the anode to surrounding air to cool the anode. The system also includes a liquid channel formed in the anode, wherein the liquid channel includes a cooling liquid. The liquid channel is located adjacent the target wherein heat from the focal spot is transferred to the cooling liquid to cool the focal spot wherein the heat transfer element, liquid channel and anode are unistructurally formed. Further, the cooling system includes a circulation pump that moves the cooling liquid in the liquid channel.

An X-ray imaging apparatus according to an embodiment of the present disclosure includes an X-ray tube, a photon counting X-ray detector, and a filter unit. A generating unit of the X-ray tube is configured to generate X-rays. The photon counting X-ray detector is configured to count photons contained in the X-rays. The filter unit is provided between the X-ray tube and the photon counting X-ray detector. The filter unit includes a first filter and a second filter. The first filter is configured to shape a spectrum of the X-rays. The second filter is configured to generate X-ray fluorescence on the basis of X-rays related to a spectrum resulting from the shaping by the first filter.

An X-ray imaging apparatus according to an embodiment of the present disclosure includes an X-ray tube, a photon counting X-ray detector, and a filter unit. A generating unit of the X-ray tube is configured to generate X-rays. The photon counting X-ray detector is configured to count photons contained in the X-rays. The filter unit is provided between the X-ray tube and the photon counting X-ray detector. The filter unit includes a first filter and a second filter. The first filter is configured to shape a spectrum of the X-rays. The second filter is configured to generate X-ray fluorescence on the basis of X-rays related to a spectrum resulting from the shaping by the first filter.

Methods and system are provided for an imaging system. In one example, the imaging device, comprises a curved arm and a carrier that engages and supports the curved arm, wherein the curved arm is configured to move relative to the carrier. The imaging system further comprises a belt extending through the carrier and traversing around a periphery of the curved arm. A drive system of the imaging device comprises a motor, a drive shaft rotatably driven by the motor, and a drive pulley coupled to the drive shaft via a clutch mechanism, wherein the drive pulley is configured to rotate and engage with the belt to move the curved arm without moving the carrier, wherein the clutch mechanism is configured to switch between an engaged state and a disengaged state, wherein the engaged state comprises the driveshaft being rotatably coupled to the drive pulley and wherein the disengaged state comprises where the driveshaft is uncoupled from the drive pulley, and wherein the clutch mechanism is configured to switch between the engaged state and the disengaged state in response to a force applied to the curved arm.

The present application provides a combined machine head and a ray imaging device, wherein the combined machine head comprises: a housing, having an enclosed cavity; a ray tube, arranged in the enclosed cavity; and a pump and a pipe, arranged in the enclosed cavity; wherein the pump is arranged on one side away from an anode of the ray tube, the pipe has a first end connected with an outlet of the pump and a second end extending to be near the anode of the ray tube; or the pump is arranged near the anode of the ray tube, the pipe has a first end connected to an inlet of the pump and a second end extending to one side away from the anode of the ray tube.

A radiography apparatus includes a radiation generation unit that has a plurality of radiation sources generating radiation toward a subject, a C-arm that supports the radiation generation unit in a first end portion as one end, a radiography unit that is provided in a second end portion as the other end of the C-arm to face the radiation generation unit and images the subject using radiation, an imaging direction designation unit that designates an imaging direction of the subject, and a radiation source selection unit that selects the radiation source for use in imaging among the plurality of radiation sources using the designation of the imaging direction.

An x-ray based cement evaluation tool for measurement of the density of material volumes within single, dual and multiple-casing wellbore environments is provided, the tool including at least an internal length comprising a sonde section, wherein said sonde section further comprises an x-ray source; a radiation shield for radiation measuring detectors; sonde-dependent electronics; and a plurality of tool logic electronics and PSUs, wherein the tool uses x-rays to illuminate the formation surrounding a borehole and a plurality of detectors are used to directly measure the density of the cement annuli and any variations in density within. Detectors used to measure casing standoff such that other detector responses are compensated for tool stand-off and centralization; a plurality of reference detectors is used to monitor the output of the x-ray source, and a shortest-axial offset detector is configured to distribute incoming photons into energy classifications such that photoelectric measurements may be made.

An x-ray based cement evaluation tool for measurement of the density of material volumes within single, dual and multiple-casing wellbore environments is provided, the tool including at least an internal length comprising a sonde section, wherein said sonde section further comprises an x-ray source; a radiation shield for radiation measuring detectors; sonde-dependent electronics; and a plurality of tool logic electronics and PSUs, wherein the tool uses x-rays to illuminate the formation surrounding a borehole and a plurality of detectors are used to directly measure the density of the cement annuli and any variations in density within. Detectors used to measure casing standoff such that other detector responses are compensated for tool stand-off and centralization; a plurality of reference detectors is used to monitor the output of the x-ray source, and a shortest-axial offset detector is configured to distribute incoming photons into energy classifications such that photoelectric measurements may be made.