Patent Number: 
Section: claims

1. An installation case for a radiation device comprising:a case body; anda collimator fixedly connected with the case body, the collimator being provided with a beam exit aperture and the case body being provided with a beam exit openings;at least a layer of shielding device provided within the case body, the at least a layer of shielding device is made of a material that can shield a radioactive ray, and between the at least a layer of shielding device and the case body, there is a space in which liquid can flow and parts can be installed;wherein the collimator and the at least a layer of shielding device are integrally formed, or the collimator and the at least a layer of shielding device are two separate parts and are fixedly connected with each other; wherein the at least a layer of shielding device is provided with a ray exit aperture, and wherein the ray exit aperture, the beam exit aperture, and the beam exit opening are coaxial; andwherein the at least a layer of shielding device is in a cylindrical or prismatic shape and comprises a cylindrical body including two end openings, a first end cover and a second end cover, wherein the first end cover and the second end cover are fixedly connected with the two end openings of the cylindrical body, respectively, and at least one of the first end cover, the second end cover, and the cylindrical body is provided with a fluid channel and/or a circuit channel. 2. The installation case for a radiation device according to claim 1, wherein:the radioactive ray is an x-ray;the at least a layer of shielding device is made of insulation material;with the at least a layer of shielding device comprises multiple layers of shielding device of which an inner layer of the multiple layers of shielding device is located inwardly of an outer layer of the multiple layers of shielding device, and between the inner layer of the multiple layers of shielding device and the outer layer of the multiple layers of shielding device, and between the case body and an outermost layer of the multiple layers of shielding device, there are spaces for flowing of liquid and mounting of parts. 3. The installation case for a radiation device according to claim 2, wherein: the circuit channel and/or the fluid channel is a through hole in a bent shape or an oblique hole provided in at least one of the first end cover, the second end cover and the cylindrical body; or at least one of the first end cover, the second end cover and the cylindrical body is in a dual-layer structure that is formed by superimposing an outer plate and an inner plate, andwherein a liquid flowing cavity is provided between the outer plate and the inner plate, and both of the outer plate and the inner plate are provided with a flow guiding orifice communicating with the liquid flowing cavity, and the fluid channel is constituted by the flow guiding orifices and the liquid flowing cavity, and the orthographic projection of the flow guiding orifice in the outer plate in the axial direction thereof and the flow guiding orifice provided in the inner plate are entirely staggered. 4. The installation case for a radiation device according to claim 3, wherein: the bent shape is a right-angle polygonal-line shape;both of the first and second end covers are provided with the fluid channels and the circuit channels;a plurality of the flow guiding orifices are distributed on the outer plate or the inner plate of the first end cover or the second end cover along the circumferential direction of the cylindrical body at equal angle intervals, and the distances between the respective flow guiding orifices and the axis of the cylindrical body are equal with each other;the cylindrical body is provided with inner screw threaded tubes embedded therein, and the inner screw threaded tubes each are provided with inner screw thread, and the portion of a connection bolt having outer screw thread passes through the outer plate and engages with the inner screw thread of the inner screw threaded tube, so that the cylindrical body and the first and second end covers are connected and fixed together;the inner plate is fixedly provided with a positioning pole which is embedded in a positioning counter bore in the outer plate and is tightly fitted with the positioning counter bore;a step portion in a step shape is provided at the inside end edge of the cylindrical body, and the step portion bears against the edge of the inner plate. 5. The installation case for a radiation device according to claim 1, wherein: the shielding device is made of lead oxide;the beam exit opening is filled with a blocking window, and the blocking window is made of a material through which the radioactive ray can transmit, and the blocking window functions to realize liquid and gas seal between the inside of the case body and the outside of the case body;the case body comprises a main body portion including two end openings, a first case cover and a second case cover, wherein:the first case cover and the second case cover are fixedly provided at the two end openings of the main body portion, respectively, the main body portion is integrally formed, and the material for the first case cover and the second case cover is the same as that for the main body portion. 6. The installation case for a radiation device according to claim 5, wherein: the shielding device is made of trilead tetroxide;the main body portion is made of aluminum or aluminum alloy material and is formed by using a stretch forming process or a wire electrode cutting process;sealing strips are provided between the first case cover and the main body portion and/or between the second case cover and the main body portion, wherein: the end face of the main body portion is provided with a step face or a groove, and the sealing strip is provided on the step face or provided in the groove and extends beyond the end face of the main body portion, and the first case cover and/or the second case cover are close to the surface of the main body portion and press against the portions of the sealing strips extending beyond the end face of the main body portion, or a step face or groove is provided on an edge of the first case cover and/or the second case cover, the sealing strip is provided on the step face or provided in the groove and extends beyond the edge of the first case cover and/or the second case cover, and the main body portion is close to the surface of the first case cover and/or the second case cover and presses against the portions of the sealing strips extending beyond the edge of the first case cover and/or the second case cover. 7. An oil-cooling circulation system, comprising:a liquid-filled box filled with an insulation liquid; anda cooling device for reducing the temperature of the insulation liquid, and the cooling device comprises an oil pump, a heat radiator including a liquid inlet, a liquid outlet, and a cooling fan;wherein:the liquid-filled box is constituted by an installation case for a radiation device, the installation case comprising a case body and a collimator fixedly connected with the case body, the collimator being provided with a beam exit aperture and the case body being provided with a beam exit opening, the installation case further comprising a layer or layers of shielding devices provided within the case body, the layer or layers of shielding devices being made of a material that can shield a radioactive ray, and defining, between the layer or layers of shielding devices and the case body, a space in which liquid can flow and parts can be installed, the layer or layers of shielding devices being in a cylindrical or prismatic shape and comprising a cylindrical body including two end openings, a first end cover and a second end cover, wherein the first end cover and the second end cover are fixedly connected with the two end openings of the cylindrical body, respectively, and at least one of the first end cover, the second end cover, and the cylindrical body is provided with a fluid channel and/or a circuit channel;the heat radiator is located outside of the liquid-filled box, the liquid inlet of the heat radiator is communicated with a liquid outlet of the liquid-filled box, and the liquid outlet of the heat radiator is communicated with a liquid inlet of the liquid-filled box;the oil pump provides a motive power for circulation between the insulation liquid in the liquid-filled box and the insulation liquid in the heat radiator;the cooling fan dissipates the heat from the heat radiator in such a way that the flow of ambient air around the heat radiator is expedited. 8. The oil-cooling circulation system according to claim 7, wherein:the cooling device further comprises a frame-shaped bracket hooding the heat radiator and the cooling fan, and the bracket is fixedly connected with the liquid-filled box;the oil pump is a DC brushless submersible pump;the oil pump is fixedly provided on the inner wall of the liquid-filled box and is located between the liquid-filled box and the layer or layers of shielding devices, or the oil pump is fixedly provided in the heat radiator; andthe oil-cooling circulation system further comprising a liquid outlet and a liquid inlet located in the fluid channel;the oil pump comprising a liquid suction port facing toward the liquid outlet of the layer or layers of shielding devices, or the liquid suction port of the oil pump being in fluid communication with the liquid outlet of the layer or layers of shielding devices via a conduit;wherein the liquid inlet of the layer or layers of shielding devices is communicated with a liquid inputting pipe, the liquid outlet of the liquid-filled box is communicated with a liquid introducing pipe, and a liquid outputting port of the liquid introducing pipe faces toward a liquid inputting port of the liquid inputting pipe, or the liquid inlet of the layer or layers of shielding devices is communicated with the liquid outlet of the liquid-filled box via a conduit. 9. An X-ray generator comprising:an X-ray tube comprising a cathode and an anode, a high frequency and high voltage generator, a filament power supplying module and the oil-cooling circulation system according to claim 7, wherein:the X-ray tube is mounted within the layer or layers of shielding devices, and the X-ray emitted from the X-ray tube passes through the ray exit aperture, the beam exit aperture, and the beam exit opening in this order and radiates out of the case body of the installation case for a radiation device;the high frequency and high voltage generator is electrically connected with the cathode and the anode of the X-ray tube;the filament power supplying module is electrically connected with the cathode of the X-ray tube. 10. The X-ray generator according to claim 9, wherein:the layer or layers of shielding devices device further comprise a circuit channel, the high frequency and high voltage generator is electrically connected with the cathode and the anode of the X-ray tube via wires or interfaces passing through the circuit channel, and the filament power supplying module is electrically connected with the cathode of the X-ray tube via wires or interfaces passing through the circuit channel;at least some of modules constituting the high frequency and high voltage generator are located between the case body and the layer or layers of shielding devices, and a power supply external to the case body and the rest of the modules constituting the high frequency and high voltage generator are located outside of the case body;the case body is provided with a wire exit channel, and those of the modules constituting the high frequency and high voltage generator located in the case body are electrically connected with those modules located outside of the case body via wires or interfaces passing through the wire exit channel, or the high frequency and high voltage generator is electrically connected with the external power supply via wires or interfaces passing through the wire exit channel;the layer or layers of shielding devices comprise a cylindrical body, a first end cover, and a second end cover, and wherein the first end cover and the second end cover are fixedly connected with two end openings of the cylindrical body, respectively;at least one of the first end cover, the second end cover, and the cylindrical body is provided with a fluid channel and the circuit channel. 11. The X-ray generator according to claim 10, wherein: both of the first end cover and the second end cover are a dual-layer structure constituted by laminating an outer plate and an inner plate, and both of the first end cover and the second end cover are provided with the circuit channel, wherein:the circuit channel provided in the first end cover comprises a cathode positioning aperture provided in the inner plate of the first end cover and a wire routing aperture provided in the outer plate of the second end cover, and in the X-ray tube, a sheath for protecting the cathode is embedded in the cathode positioning hole, and the wire routing aperture comprises a longitudinal aperture coincident with/parallel to the axial direction of the X-ray tube and a transverse aperture communicating with the longitudinal aperture, the axial direction of the transverse aperture being perpendicular to the axial direction of the longitudinal aperture, and the cathode of the X-ray tube is led out from the wire routing aperture from an inside of the sheath by two wires;the circuit channel provided in the second end cover comprises anode positioning apertures provided in the inner plate and the outer plate of the second end cover, a conductive stud orderly passes through the anode positioning apertures provided in the outer plate and the inner plate of the second end cover, and the conductive stud is provided with an outer screw threaded portion which is engaged with an anode screw hole provided in the anode, the portion of the conductive stud far away from the anode is provided with a positioning screw hole, a conductive screw is provided with an outer screw threaded portion which is engaged with the positioning screw hole, and a wire electrically connected with the anode of the high frequency and high voltage generator is sandwiched between a head of the conductive screw and the conductive stud;the inner plate of the second end cover is provided with at least one anode position-limit hole, the anode is provided with a position-limit screw hole, a positioning stud is provided with an outer screw threaded portion which is engaged with the position-limit screw hole, and the end of the positioning stud far away from the position-limit screw hole is inserted in the anode position-limit hole;of the first end cover and the second end cover are provided with the fluid channels, both of the first end cover and the second end cover are the dual-layer structure constituted by the laminated outer plate and inner plate, there is a liquid flowing cavity between the outer plate and the inner plate, and both of the inner plate and the outer plate are provided with flow guiding orifices communicated with the liquid flowing cavity, and the fluid channel is constituted by the flow guiding orifices and the liquid flowing cavity;the anode is in a hood shape and covers the end of a glass hood of the X-ray tube far away from the cathode, a liquid flowing space is provided between the anode and the outer circumferential surface of the glass hood of the X-ray tube, and the anode is provided with liquid circulating holes respectively communicating with the liquid flowing space and the flow guiding orifice provided in the inner plate of the second end cover. 12. The X-ray generator according to claim 11, wherein: the bent shape is a right-angle polygonal-line shape;the case body comprises a main body portion, a first case cover and a second case cover, wherein:the first case cover and the second case cover are fixedly provided at the two end openings of the main body portion, respectively;constituent modules of the high frequency and high voltage generator comprise a first rectification and voltage regulation module, a high frequency inverter, a high voltage transformer and a voltage-doubling rectification module which are electrically connected with each other in this order, wherein:the first rectification and voltage regulation module is electrically connected with the external power supply and is configured to take electrical energy required for loading a DC high voltage to the cathode and the anode of the X-ray tube from the external power supply;the voltage-doubling rectification module is electrically connected with the cathode and the anode of the X-ray tube;among the constituent modules of the high frequency and high voltage generator, at least the high voltage transformer and the voltage-doubling rectification module are fixedly provided between the case body and the shielding device;the high voltage transformer is fixedly provided on the collimator, the first case cover, the second case cover or the shielding device, and the voltage-doubling rectification module is fixedly provided on a circuit board, wherein:at least one of two ends of the circuit board bears against a position-limit protruding piece fixedly provided on the first case cover or the second case cover, and the circuit board is fixed on the position-limit protruding pieces by fasteners, or at least one of the two ends of the circuit board is inserted in a groove provided on the first case cover or the second case cover, and the middle region of the circuit board is fixed on the main body portion by fasteners. 13. The X-ray generator according to claim 12, wherein: the X-ray generator further comprises a monitor system, and the monitor system comprises a signal sampling module, a sampled-signal processing module, a logic decision and control module, and an auxiliary power supply module configured to supply power for the logic decision and control module, wherein:the signal sampling module is located between the case body and the shielding device or is located within the shielding device;the signal sampling module is used for detecting electric signals on the cathode or the anode of the X-ray tube, the temperature of the insulation liquid and the flow rate of the insulation liquid flowing into or flowing out of the case body, and sends the detected electric signals to the sampled-signal processing module;the sampled-signal processing module is electrically connected with the signal sampling module and the logic decision and control module;the sampled-signal processing module is configured for filtering the electric signals or converting the electric signals into the detection result in a digital form through analog-digital conversion and sending the detection result in a digital form to the logic decision and control module;the logic decision and control module is also electrically connected with at least one of the high frequency and high voltage generator, the filament power supply module, and the cooling device;the logic decision and control module automatically calls previously-stored control instructions according to the detection result based on predetermined correspondence rules between the detection result and the control instructions, and controls at least the output voltage or current of the high frequency and high voltage generator or the filament power supply module according to the control instructions, or controls power consumption of the cooling device according to the control instructions. 14. The X-ray generator according to claim 13, wherein: the filament power supply module comprises a second rectification and voltage regulation module electrically connected with the logic decision and control module, a filament inverter and a filament transformer electrically connected with the filament inverter and the cathode of the X-ray tube; the filament transformer is fixedly provided in the case body, and is configured to convert the voltage output from the filament inverter into a high frequency pulse voltage required for the cathode of the X-ray tube and to output the high frequency pulse voltage to the cathode of the X-ray tube;the first rectification and voltage regulation module, the high frequency inverter, the logic decision and control module, the rectification and voltage regulation module, the filament inverter and the auxiliary power supply module are fixedly provided on the outer surface of the case body or in a control box provided outside of the case body;the wires or interfaces passing through the wire exit channel provided in the case body are aviation plugs that provide liquid and gas seal between the inside of the case body and the outside of the case body, wherein the high voltage transformer and the high frequency inverter are electrically connected with each other via the aviation plugs, the signal sampling module and the sampled-signal processing module are electrically connected with each other via the aviation plugs or the filament inverter and the filament transformer are electrically connected with each other via the aviation plugs.