CN211235602U - X-ray CT apparatus - Google Patents

Abstract

The utility model provides an X ray CT device, place the marble platform above the base, the X-ray tube is fixed on the base, two planer-type marble framves are fixed at the both ends of marble platform top, install on planer-type marble frame two A linear electric motor's stiff end, B linear electric motor's stiff end is installed above A linear electric motor motion end, two C linear electric motor's stiff end is installed on marble platform perpendicular, two D linear electric motor's the stiff end is fixed to the higher authority of C linear electric motor motion end, the stiff end of two fixed E linear electric motor on D linear electric motor's the motion end, fixed objective table above E linear electric motor's the motion end, the measured object is placed on the objective table. The device replaces a mechanical turntable with double-circle linkage, solves the problem that the precision of a mechanical structure is difficult to meet the requirement, and overcomes the defects of large size, high cost and insufficient precision of the turntable. The measured object and the detector are respectively controlled in the X direction and the Y direction in the plane, and the corresponding motion trail is completed more accurately, conveniently and rapidly.

Description

X-ray CT apparatus

Technical Field

The utility model relates to an X ray CT device, concretely says so and relates to a novel X ray CT device of CL scanning mode.

Background

The CL technique belongs to a branch of the CT technique, and utilizes high-resolution microscopic DR projection information of different orientations of an object to reversely calculate the spatial distribution of the ray attenuation coefficient of an internal material of the object. However, the CL technique is different from the conventional CT technique, and it adopts a three-dimensional digital tomography method of oblique ray scanning, and reconstructs a three-dimensional tomographic image of the scanning area by using a two-dimensional digital projection sequence acquired by a photoelectric digital converter of a radiation image on the other side. The tomographic image of the layer separation is mainly used for scanning and reconstructing the plate-shaped structure. The method realizes the spatial positioning of manufacturing defects of the plate-shaped electronic device on one hand and the copying of a circuit diagram of the device on the other hand so as to guide CAD design. All information of a measured object is collected under the condition that the measured object is required to be inclined at a certain angle, the diameter of the motion trail of the detector is large because the size of the focal length of X-ray imaging is large, and the precision is difficult to guarantee by adopting a traditional rotary table to realize motion. Because the overall dimension of the plane of the measured object with a plate-shaped structure is generally very large, all required information can not be obtained by scanning in one period, the required information needs to be detected in blocks and finally collected, spliced, reconstructed and imaged, and the previous annular acquisition has a lot of unnecessary repeated information and the scanning at some positions even obtains incomplete rings, thereby bringing certain difficulty to the calculation and reconstruction.

Disclosure of Invention

To the problem that exists in the aspect of the inside quality testing of current platelike structure testee, the utility model provides a can replace mechanical revolving stage, solve the X ray CT device that the mechanical structure precision is difficult to reach the requirement.

The concrete technical measures for solving the problems are as follows:

an X-ray CT apparatus, characterized in that: the marble platform 2 is placed on the base 1, the hollow part of the X-ray tube 10 positioned in the middle of the marble platform 2 is fixed on the base 1, the two gantry marble frames 3 are fixed at two ends above the marble platform 2, the fixed ends of the two A linear motors 4 are installed on the gantry marble frames 3, the fixed end of the B linear motor 5 is installed on the moving ends of the two A linear motors 4, the fixed ends of the two C linear motors 9 are installed on the vertical surface of the hollow part of the marble platform 2, the fixed ends of the two D linear motors 8 are fixed on the moving ends of the two C linear motors 9, the fixed ends of the two E linear motors 7 are fixed on the moving ends of the two D linear motors 8, the objective table 14 is fixed on the moving ends of the two E linear motors 7, the object to be measured 12 is placed on the objective table 14, the object to be measured 12 moves along the A track 13, the flat panel detector 6 moves, the center of the measured object 12 and the center of the flat panel detector 6 are in one-to-one corresponding double-circle linkage all the time on the light path with the inclination angle theta.

The utility model discloses an actively the effect: the device adopts a double-circle linkage structure mode to replace a mechanical turntable, solves the problem that the precision of the mechanical structure of the turntable is difficult to meet the requirement, and overcomes the defects of large size, high cost and insufficient precision of the turntable. The measured object and the detector are controlled in the X direction and the Y direction in the plane respectively, and the corresponding movement track is completed more accurately, conveniently and rapidly. The scanning mode of the device can realize local block scanning, so that the rotation center scanning only needs to be continuously changed by proper distance, and the whole required information can be collected by slightly overlapping the edges. Much less unnecessary repetition information is obtained than in the previous annular acquisition. Thus, time is effectively saved and efficiency is improved. In addition, the rotation center of the measured object is controlled in the X direction and the Y direction in the plane of the measured object respectively, and the rotation center is changed only by simply changing the motion track of the measured object. No redundant action is needed, the time is saved more effectively, and the efficiency is improved.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a right side view of FIG. 1;

fig. 4 is a schematic diagram of the movement of the present invention;

fig. 5 is a schematic diagram of the program control of the present invention.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

An X-ray CT device is disclosed, as shown in figure 1, figure 2 and figure 3, a marble platform 2 is placed on a base 1, an X-ray tube 10 is positioned at a hollow part in the middle of the marble platform 2, the light-emitting position is ensured to be positioned above the marble platform, and the X-ray tube is fixed on the base 1. Two gantry marble racks 3 are fixed at two ends above the marble platform 2 to ensure that the upper surface is coplanar. The fixed ends of the two A linear motors 4 are arranged on the gantry type marble frame 3, and simultaneously drive the B linear motor 5 to realize the motion of the flat panel detector 6 in the Y direction. The fixed end of the B linear motor 5 is arranged above the moving ends of the two A linear motors 4, so that the flat panel detector 6 can move in the X direction. The fixed ends of the two C linear motors 9 are installed on the vertical surface of the hollowed-out position of the marble platform 2, the C linear motors 9 are driven simultaneously, the movement of the measured object 12 in the Z direction is achieved, the position of the measured object 12 in the light path is adjusted, and therefore the imaging magnification is changed. The fixed ends of the two D linear motors 8 are fixed on the moving ends of the two C linear motors 9. And meanwhile, the D linear motors 8 are driven to realize the motion of the measured object 12 in the Y direction, the fixed ends of the two E linear motors 7 are fixed on the motion ends of the two D linear motors 8, an object stage 14 is fixed on the motion ends of the two E linear motors 7, the E linear motors 7 are driven to realize the motion of the measured object 12 in the X direction, and the measured object 12 is placed on the object stage 14. The measured object 12 moves along the track A13, the flat panel detector 6 moves along the track B11, and the center of the measured object 12 and the center of the flat panel detector 6 are in one-to-one corresponding double-circle linkage on the light path with the inclination angle theta all the time.

Fig. 4 is a schematic diagram of the movement of the present invention. The object 12 to be measured is inclined by an angle theta relative to the X-ray optical path, and the object 12 to be measured moves along the locus of points on the plane where the object 12 is located and passing through the inclination angle theta optical path. Meanwhile, the flat panel detector 6 moves on the plane where the flat panel detector is located along the locus of points passing through the inclination angle theta light path, the angular speed of the object to be measured 12 is the same as that of the flat panel detector 6, and the two planes where the flat panel detector is located are in parallel double-circle linkage. The detection of the object 12 in a certain area is completed after the detection of one week is completed, and then the object 12 is moved to perform the detection of the next adjacent area.

Fig. 5 is a schematic diagram of the program control of the present invention. The motion control system of the device consists of an upper computer, a PLC (programmable logic controller), a linear motor driver and a linear motor. The upper computer and the PLC are communicated through OPC, and the PLC can control linear motor drivers of all shafts through Ethernet or field bus. The motion control process is as follows: and the upper computer software sends control signals such as a positioning distance, a positioning speed and the like to the PLC. After receiving the control signal, the PLC sends out a control signal to each linear motor driver through a series of logic operations, and the linear motor drivers control the corresponding linear motors to move after receiving the signal. The grating ruler feeds back the position value of the motor rotor to the linear motor driver, and the linear motor driver feeds back the position, speed and other information of the motor rotor to the PLC. The PLC controller feeds back real-time position, speed, positioning completion signals, limit point signals, fault signals and the like of each shaft to the upper computer, and finally the signals are displayed on a software interface of the upper computer.

Claims (1)

1. An X-ray CT apparatus, characterized in that: the marble platform (2) is placed on the base (1), the hollowed-out part of the X-ray tube (10) positioned in the middle of the marble platform (2) is fixed on the base (1), the two gantry type marble frames (3) are fixed at two ends above the marble platform (2), the fixed ends of the two A linear motors (4) are arranged on the gantry type marble frames (3), the fixed end of the B linear motor (5) is arranged on the moving ends of the two A linear motors (4), the fixed ends of the two C linear motors (9) are arranged on the vertical surface of the hollowed-out part of the marble platform (2), the fixed ends of the two D linear motors (8) are fixed on the moving ends of the two D linear motors (8), the fixed ends of the two E linear motors (7) are fixed on the moving ends of the two E linear motors (7), and the objective table (14) is fixed on the moving ends of the two E linear motors (7), the measured object (12) is placed on the object stage (14), the measured object (12) moves along the track A (13), the flat panel detector (6) moves along the track B (11), and the center of the measured object (12) and the center of the flat panel detector (6) are in one-to-one corresponding double-circle linkage on the light path with the inclination angle theta all the time.

Images