CN220584094U - X-ray detection equipment - Google Patents

Abstract

The utility model discloses X-ray detection equipment, which comprises a frame, a driving motor and an X-ray source assembly which are arranged on the frame, a flat plate receiving assembly and a placing assembly which are arranged on the frame, a first driving assembly which is arranged on the flat plate receiving assembly, a second driving assembly which is arranged on the X-ray source assembly, and a linkage belt, wherein the placing assembly is positioned between the X-ray source assembly and the flat plate receiving assembly, the first driving assembly is in transmission connection with the driving motor, and the first driving assembly is in transmission connection with the second driving assembly through the linkage belt; the first driving assembly is driven by the driving motor to drive the flat receiving assembly to move, the second driving assembly is driven by the linkage belt to drive the X-ray source assembly to move, the first driving assembly and the second driving assembly can be driven by the driving motor to work, the flat receiving assembly and the X-ray source assembly are driven to move simultaneously, the flat receiving assembly and the X-ray source assembly are kept in a coaxial state all the time, and the synchronization rate is high.

Description

X-ray detection equipment

Technical Field

The utility model relates to the technical field of detection, in particular to X-ray detection equipment.

Background

The principle of the industrial X-ray detection is as follows: when X-rays are absorbed by a substance, molecules constituting the substance are decomposed into positive and negative ions, called ionization, and the amount of ions is proportional to the amount of X-rays absorbed by the substance. The amount of X-rays can be calculated by measuring the degree of ionization with a meter by generating ionization by air or other substances. Converting into digital signals by an imager, restoring into images by computer-aided software, and then judging, marking, storing and the like; the existing X-ray detection equipment adopts a split type independent module control mode, the movement of three axes of XYZ is controlled independently, an X-ray source and a panel receiver need to be kept in a coaxial state in the X-ray imaging process, the independent electric module control has a control progress requirement, the requirement on synchronization is very high, and the independent control module has high cost.

Disclosure of Invention

In order to solve the above problems, the present utility model provides an X-ray detection apparatus, in which a driving motor is provided to drive a first driving component to work to drive a flat panel receiving component to move, and a linkage belt to drive a second driving component to work to drive an X-ray source component to move, so that the driving motor can drive the first driving component and the second driving component to work at the same time, and drive the flat panel receiving component and the X-ray source component to move at the same time, so that the flat panel receiving component and the X-ray source component are always kept in a coaxial state, the synchronization rate is high, and the cost of a control module is reduced.

In order to achieve the above purpose, the technical scheme adopted by the utility model is to provide an X-ray detection device, which comprises a frame, a driving motor and an X-ray source assembly which are arranged on the frame, a flat plate receiving assembly and a placing assembly which are arranged on the frame, a first driving assembly which is arranged on the flat plate receiving assembly, a second driving assembly which is arranged on the X-ray source assembly, and a linkage belt, wherein the placing assembly is positioned between the X-ray source assembly and the flat plate receiving assembly, the first driving assembly is in transmission connection with the driving motor, and the first driving assembly is in transmission connection with the second driving assembly through the linkage belt.

As a preferred scheme, the first driving assembly comprises a first left mounting seat and a first right mounting seat which are mounted on the flat plate receiving assembly, a first left driving wheel mounted on the first left mounting seat, a driving shaft mounted on the first right mounting seat, a first right driving wheel mounted on the driving shaft, a first driving belt and a first connecting piece mounted on the first driving belt, wherein the driving shaft is in driving connection with the driving motor, one end of the first driving belt is mounted on the first left driving wheel, the other end of the first driving belt is mounted on the first right driving wheel, and the first right driving wheels are arranged in a plurality of and spaced mode.

As a preferable scheme, the second driving assembly comprises a second left mounting seat and a second right mounting seat which are mounted on the X-ray source assembly, a second left driving wheel mounted on the second left mounting seat, a second right driving wheel mounted on the second right mounting seat, a second driving belt and a second connecting piece mounted on the second driving belt, one end of the second driving belt is mounted on the second left driving wheel, the other end of the second driving belt is mounted on the second right driving wheel, a plurality of second right driving wheels are arranged at intervals, one end of the linkage belt is mounted on the first right driving wheel, and the other end of the linkage belt is mounted on the second right driving wheel.

As a preferable scheme, the flat plate receiving assembly comprises a first sliding seat and a second sliding seat which are arranged on the frame, a first sliding block arranged on the first sliding seat, a second sliding block arranged on the second sliding seat, a flat plate receiving frame, a flat plate motor and a flat plate sliding unit which are arranged on the flat plate receiving frame, a receiving plate arranged on the flat plate sliding unit and a flat plate receiver arranged on the receiving plate, wherein one end of the flat plate receiving frame is arranged on the first sliding block, the other end of the flat plate receiving frame is arranged on the second sliding block, the flat plate motor is in transmission connection with the flat plate sliding unit, and the first connecting piece is connected with the flat plate receiving frame.

As a preferable scheme, the X-ray source assembly comprises a third sliding seat and a fourth sliding seat which are arranged on the frame, a third sliding block arranged on the third sliding seat, a fourth sliding block arranged on the fourth sliding seat, an X-ray frame and an X-ray module arranged on the X-ray frame, one end of the X-ray frame is arranged on the third sliding block, the other end of the X-ray frame is arranged on the fourth sliding block, and the second connecting piece is connected with the X-ray frame.

As a preferred scheme, place the subassembly including install in first slide and the second of placing of frame place the slide, install in first place the motor of placing of slide, install in first place the slide first place the slider, install in second place the slider, rack, install in the placing plate of rack are placed to the second of placing the slide, first place the motor respectively with first place the slider with the slider transmission is placed to the second and is connected, rack one end install in first place the slider, the rack other end install in the slider is placed to the second, place the board and be located X-ray module with between the flat receiver.

As a preferred scheme, still include install in the controller of frame and control the subassembly, the controller respectively with drive assembly, X ray source subassembly, dull and stereotyped receiving element, place the subassembly and control the subassembly electricity and be connected, control the subassembly including install in the frame control the frame, install in control the display screen of frame and control the platform, the display screen with control the platform all with the controller electricity is connected.

As a preferable scheme, the frame is provided with a plurality of moving wheels which are arranged at intervals.

As a preferable mode, the frame is provided with a plurality of radiating fans which are arranged at intervals.

As a preferred scheme, the frame has siren and control button, the siren with control button all with the controller electricity is connected, control the button and be a plurality of and the interval setting.

The utility model has the beneficial effects that: the first driving assembly is driven by the driving motor to drive the flat receiving assembly to move, the second driving assembly is driven by the linkage belt to drive the X-ray source assembly to move, the first driving assembly and the second driving assembly can be driven by the driving motor to simultaneously drive the flat receiving assembly and the X-ray source assembly to simultaneously move, the flat receiving assembly and the X-ray source assembly are always kept in a coaxial state, the synchronization rate is high, and the cost of the control module is reduced.

Drawings

Fig. 1 is a schematic view of the overall structure of an X-ray detecting apparatus of the present utility model.

Fig. 2 is a schematic structural view of the X-ray detecting apparatus of fig. 1 with a protective frame removed.

Fig. 3 is a schematic structural view of an X-ray source assembly in the X-ray detecting apparatus of fig. 2.

Fig. 4 is a schematic structural view of a panel receiving assembly in the X-ray detecting apparatus of fig. 2.

Fig. 5 is a schematic structural view of a placement component in the X-ray detection apparatus of fig. 2.

Fig. 6 is a schematic structural view of a first driving assembly in the X-ray detecting apparatus of fig. 2.

Fig. 7 is a schematic structural view of a second driving assembly in the X-ray detecting apparatus of fig. 2.

Fig. 8 is a schematic structural diagram of a manipulation assembly in the X-ray detection apparatus of fig. 2.

Reference numerals illustrate: 100. a frame; 110. a moving wheel; 120. a heat radiation fan; 130. a protective frame; 200. a driving motor; 300. an X-ray source assembly; 310. a third slider; 320. a fourth slider; 330. a third slider; 340. a fourth slider; 350. an X-ray frame; 360. an X-ray module; 400. a panel receiving assembly; 410. a first slider; 420. a second slider; 430. a first slider; 440. a second slider; 450. a panel receiving rack; 460. a flat motor; 470. a flat plate sliding unit; 480. a receiving plate; 490. a plate receiver; 500. placing the assembly; 510. a first placement slider; 520. a second placement slider; 530. a first placement motor; 540. a first placement slider; 550. a second placement slider; 560. a placing rack; 570. placing a plate; 600. a first drive assembly; 610. a first left mount; 620. a first right mount; 630. a first left driving wheel; 640. a transmission shaft; 650. a first right driving wheel; 660. a first belt; 670. a first connector; 700. a second drive assembly; 710. a second left mounting seat; 720. a second right mount; 730. a second left driving wheel; 740. a second right driving wheel; 750. a second belt; 760. a second connector; 800. a linkage belt; 900. a manipulation assembly; 910. a control rack; 920. a display screen; 930. a console.

Detailed Description

The following description of the embodiments of the present utility model will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1 to 8, the present utility model provides an X-ray detecting apparatus, comprising a gantry 100, a driving motor 200 and an X-ray source assembly mounted on the gantry 100, a flat panel receiving assembly 400 and a placement assembly 500 mounted on the gantry 100, a first driving assembly 600 mounted on the flat panel receiving assembly 400, a second driving assembly 700 mounted on the X-ray source assembly, and a linkage belt 800, the placement assembly 500 being located between the X-ray source assembly and the flat panel receiving assembly 400, the first driving assembly 600 being in transmission connection with the driving motor 200, the first driving assembly 600 being in transmission connection with the second driving assembly 700 through the linkage belt 800; the first driving assembly 600 is driven to work through the driving motor 200 to drive the flat panel receiving assembly 400 to move, the linkage belt 800 drives the second driving assembly 700 to work so as to drive the X-ray source assembly 300 to move, the driving motor 200 can drive the first driving assembly 600 and the second driving assembly 700 to work simultaneously so as to drive the flat panel receiving assembly 400 and the X-ray source assembly 300 to move simultaneously, the flat panel receiving assembly 400 and the X-ray source assembly 300 are always kept in a coaxial state, the synchronization rate is high, and the cost of a control module is reduced.

The first driving assembly 600 includes a first left mounting seat 610 and a first right mounting seat 620 mounted on the panel receiving assembly 400, a first left driving wheel 630 mounted on the first left mounting seat 610, a driving shaft 640 mounted on the first right mounting seat 620, a first right driving wheel 650 mounted on the driving shaft 640, a first driving belt 660, and a first connecting piece 670 mounted on the first driving belt 660, wherein the driving shaft 640 is in driving connection with the driving motor 200, one end of the first driving belt 660 is mounted on the first left driving wheel 630, the other end of the first driving belt 660 is mounted on the first right driving wheel 650, the first right driving wheels 650 are arranged at intervals, the driving motor 200 works to drive the driving shaft 640 to rotate, and then drive the first right driving wheel 650 to rotate, and then drive the first driving belt 660 to rotate, so that the panel receiving assembly 400 is driven to move through the first connecting piece 670.

The second driving assembly 700 includes a second left mounting seat 710 and a second right mounting seat 720 mounted on the X-ray source assembly, a second left driving wheel 730 mounted on the second left mounting seat 710, a second right driving wheel 740 mounted on the second right mounting seat 720, a second driving belt 750, and a second connecting member 760 mounted on the second driving belt 750, wherein one end of the second driving belt 750 is mounted on the second left driving wheel 730, the other end of the second driving belt 750 is mounted on the second right driving wheel 740, the second right driving wheels 740 are multiple and are arranged at intervals, one end of the driving belt 800 is mounted on the first right driving wheel 650, the other end of the driving belt 800 is mounted on the second driving belt 750, the driving motor 200 is operated to drive the driving shaft 640 to rotate, the driving shaft 640 rotates to drive the first right driving wheel 650, the first right driving belt 800 rotates, the driving belt 800 rotates to drive the second right driving wheel 740, and the second right driving belt 450 rotates, so that the X-ray source assembly 300 is driven to move through the second connecting member 760.

The panel receiving assembly 400 includes a first slider 410 and a second slider 420 mounted to the frame 100, a first slider 430 mounted to the first slider 410, a second slider 440 mounted to the second slider 420, a panel receiving frame 450, a panel motor 460 and a panel sliding unit 470 mounted to the panel receiving frame 450, a receiving board 480 mounted to the panel sliding unit 470, a panel receiver 490 mounted to the receiving board 480, one end of the panel receiving frame 450 is mounted to the first slider 430, the other end of the panel receiving frame 450 is mounted to the second slider 440, the panel motor 460 is in driving connection with the panel sliding unit 470, a first connecting member 670 is connected to the panel receiving frame 450, and the panel motor 460 operates to drive the receiving board 480 to slide on the panel sliding unit 470, thereby driving the panel receiver 490 to move, so as to adjust the position of the panel receiver 490 as required.

The X-ray source assembly includes a third slider 310 and a fourth slider 320 mounted on the frame 100, a third slider 330 mounted on the third slider 310, a fourth slider 340 mounted on the fourth slider 320, an X-ray frame 350, an X-ray module 360 mounted on the X-ray frame 350, one end of the X-ray frame 350 is mounted on the third slider 330, the other end of the X-ray frame 350 is mounted on the fourth slider 340, a second connector 760 is connected with the X-ray frame 350, and the driving motor 200 can work to drive the first driving assembly 600 and the second driving assembly 700 to work at the same time, so as to drive the panel receiving assembly 400 and the X-ray source assembly 300 to move at the same time, so that the panel receiving assembly 400 and the X-ray source assembly 300 are always kept in a coaxial state, and normal and stable work is ensured.

The placement module 500 includes a first placement slide 510 and a second placement slide 520 mounted on the frame 100, a first placement motor 530 mounted on the first placement slide 510, a first placement slide 540 mounted on the first placement slide 510, a second placement slide 550 mounted on the second placement slide 520, a placement frame 560, and a placement plate 570 mounted on the placement frame 560, wherein the first placement motor 530 is respectively in transmission connection with the first placement slide 540 and the second placement slide 550, one end of the placement frame 560 is mounted on the first placement slide 540, the other end of the placement frame 560 is mounted on the second placement slide 550, the placement plate 570 is located between the X-ray module 360 and the flat panel receiver 490, the first placement motor 530 operates to drive the first placement slide 540 and the second placement slide 550 to move, and then drive the placement frame 560 to move, so as to change the position of the placement plate 570, thereby being able to cooperatively adjust the correspondence between the placement module 500, the X-ray source module 300, and the flat panel receiving module 400.

The device further comprises a controller and a control assembly 900, wherein the controller is arranged on the frame 100 and is electrically connected with the driving assembly, the X-ray source assembly, the flat panel receiving assembly 400, the placement assembly 500 and the control assembly 900 respectively, the control assembly 900 comprises a control frame 910 arranged on the frame 100, a display screen 920 arranged on the control frame 910 and a control table 930, the display screen 920 and the control table 930 are electrically connected with the controller, the control table 930 is used for inputting adjustment information, the adjustment is performed by controlling each assembly through the controller, and the display screen 920 is used for displaying the control information.

The frame 100 has a plurality of moving wheels 110, and the moving wheels 110 are arranged at intervals, so that the moving wheels 110 can move the frame conveniently.

The rack 100 is provided with a plurality of heat dissipation fans 120, the heat dissipation fans 120 are arranged at intervals, and the heat dissipation fans 120 are used for dissipating heat so as to ensure the normal operation of detection.

The gantry 100 has a protective frame 130, the protective frame 130 housing a drive assembly, an X-ray source assembly, a panel receiving assembly 400, a placement assembly 500, and a handling assembly 900.

The above embodiments are merely illustrative of the preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model, and various modifications and improvements made by those skilled in the art to the technical solution of the present utility model should fall within the scope of protection defined by the claims of the present utility model without departing from the spirit of the design of the present utility model.

Claims (10)

1. The utility model provides an X-ray detection equipment, its characterized in that includes the frame, install in driving motor and the X-ray source subassembly of frame, install in the dull and stereotyped subassembly of receiving of frame and place the subassembly, install in the dull and stereotyped first drive assembly of receiving the subassembly, install in the second drive assembly of X-ray source subassembly and linkage area, place the subassembly and be located the X-ray source subassembly with between the dull and stereotyped subassembly of receiving, first drive assembly with driving motor transmission is connected, first drive assembly with second drive assembly passes through the linkage area transmission is connected.

2. An X-ray detection apparatus according to claim 1, characterized in that: the first driving assembly comprises a first left mounting seat and a first right mounting seat which are mounted on the flat plate receiving assembly, a first left driving wheel mounted on the first left mounting seat, a driving shaft mounted on the first right mounting seat, a first right driving wheel mounted on the driving shaft, a first driving belt and a first connecting piece mounted on the first driving belt, wherein the driving shaft is in transmission connection with the driving motor, one end of the first driving belt is mounted on the first left driving wheel, the other end of the first driving belt is mounted on the first right driving wheel, and the first right driving wheels are arranged in a plurality of intervals.

3. An X-ray detection apparatus according to claim 2, characterized in that: the second driving assembly comprises a second left mounting seat and a second right mounting seat which are mounted on the X-ray source assembly, a second left driving wheel mounted on the second left mounting seat, a second right driving wheel mounted on the second right mounting seat, a second driving belt and a second connecting piece mounted on the second driving belt, one end of the second driving belt is mounted on the second left driving wheel, the other end of the second driving belt is mounted on the second right driving wheel, a plurality of second right driving wheels are arranged at intervals, one end of the linkage belt is mounted on the first right driving wheel, and the other end of the linkage belt is mounted on the second right driving wheel.

4. An X-ray detection apparatus according to claim 3, characterized in that: the flat plate receiving assembly comprises a first sliding seat and a second sliding seat which are arranged on the frame, a first sliding block arranged on the first sliding seat, a second sliding block arranged on the second sliding seat, a flat plate receiving frame, a flat plate motor and a flat plate sliding unit which are arranged on the flat plate receiving frame, a receiving plate which is arranged on the flat plate sliding unit, and a flat plate receiver which is arranged on the receiving plate, wherein one end of the flat plate receiving frame is arranged on the first sliding block, the other end of the flat plate receiving frame is arranged on the second sliding block, the flat plate motor is in transmission connection with the flat plate sliding unit, and the first connecting piece is connected with the flat plate receiving frame.

5. An X-ray detection apparatus according to claim 4, wherein: the X-ray source assembly comprises a third sliding seat and a fourth sliding seat which are arranged on the frame, a third sliding block arranged on the third sliding seat, a fourth sliding block arranged on the fourth sliding seat, an X-ray frame and an X-ray module arranged on the X-ray frame, one end of the X-ray frame is arranged on the third sliding block, the other end of the X-ray frame is arranged on the fourth sliding block, and the second connecting piece is connected with the X-ray frame.

6. An X-ray detection apparatus according to claim 5, wherein: the assembly is placed including install in first slide and the second of placing of frame place the slide, install in first place the motor of placing of slide, install in first place the slide place the slider, install in the second of placing the slide place the slider, rack, install in the placing plate of rack, first place the motor respectively with first place the slider with the slider transmission is placed to the second, rack one end install in first place the slider, the rack other end install in the slider is placed to the second, place the board be located X ray module with between the flat receiver.

7. An X-ray detection apparatus according to claim 1, characterized in that: the X-ray detector comprises a frame, a driving assembly, an X-ray source assembly, a flat plate receiving assembly, a placing assembly and a control assembly, and is characterized by further comprising a controller and a control assembly, wherein the controller is arranged on the frame and is electrically connected with the driving assembly, the X-ray source assembly, the flat plate receiving assembly, the placing assembly and the control assembly respectively, the control assembly comprises a control frame arranged on the frame, a display screen arranged on the control frame and a control table, and the display screen and the control table are electrically connected with the controller.

8. An X-ray detection apparatus according to claim 7, wherein: the frame is provided with a plurality of moving wheels which are arranged at intervals.

9. An X-ray detection apparatus according to claim 7, wherein: the frame is provided with a plurality of radiating fans which are arranged at intervals.

10. An X-ray detection apparatus according to claim 7, wherein: the frame has the siren and controls the button, the siren with control the button all with the controller electricity is connected, control the button and be a plurality of and the interval setting.