CN219493534U - X-ray detection device for multi-angle shooting detection - Google Patents

Abstract

The utility model discloses an X-ray detection device for multi-angle shooting detection, which comprises a base structure arranged on a connection limiting structure, wherein the base structure comprises a base component arranged on a driving adjustment component, the base component comprises a mounting plate with a plurality of damping shock absorbers at the bottom, the mounting plate is provided with movable wheels for moving the whole device to different working places through the bottoms of the damping shock absorbers, the base structure comprises a driving adjustment component, the driving adjustment component comprises a driving cylinder with a bearing plate above, one side of the driving cylinder is provided with a controller for controlling and adjusting parts, the driving adjustment component comprises a bearing plate, the bearing plate is provided with an X-ray detector through a connecting shaft, and the X-ray detector is provided with a driven gear meshed with a chain through the connecting shaft.

Description

X-ray detection device for multi-angle shooting detection

Technical Field

The utility model relates to the technical field of X-ray detection devices, in particular to an X-ray detection device for multi-angle shooting detection.

Background

The X-ray is a particle stream generated by the transition of electrons in atoms between two energy levels with greatly different energy levels, the wavelength of the particle stream is between 0.01 and 100 angstroms, the particle stream is an electromagnetic wave with the wavelength between ultraviolet rays and gamma rays, the X-ray has high penetrating power, and can penetrate through a plurality of substances which are not transparent to visible light, such as ink paper, timber and the like, and the invisible rays of the naked eyes can cause a plurality of solid materials to generate visible fluorescence, so that photographic films are sensitized, air ionized and other effects; x-rays were originally used for medical imaging diagnosis and X-ray crystallography; the X-ray is also a ray harmful to human body such as free radiation, and a portable X-ray flaw detector can be used when detecting parts, and the existing some electrified X-ray detection tools are turned over manually when detecting the parts, so that the mode is very inconvenient when in use.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provide an X-ray detection device for multi-angle shooting detection, so as to solve the problem that the prior charged X-ray detection tool proposed in the prior art is inconvenient to use by manually overturning the X-ray detection tool during part detection.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the X-ray detection device comprises a base structure which is arranged on a connection limiting structure, wherein the base structure comprises a base component which is arranged on a driving adjusting component, the base component comprises a mounting plate with a plurality of damping shock absorbers at the bottom, and movable wheels which move the whole device to different workplaces are arranged at the bottom of the mounting plate through the damping shock absorbers;

the foundation structure comprises a driving adjusting assembly, the driving adjusting assembly comprises a driving air cylinder, a bearing plate is arranged above the driving air cylinder, and a controller for controlling and adjusting parts is arranged on one side of the driving air cylinder.

Through adopting above-mentioned technical scheme, thereby through the two-way erection joint of damping bumper shock absorber and buffering shock attenuation effect.

Preferably, the driving adjusting assembly comprises a bearing plate, wherein the bearing plate is provided with an X-ray detector through a connecting shaft, and the X-ray detector is provided with a driven gear in meshed connection with a chain through the connecting shaft.

Through adopting above-mentioned technical scheme, thereby through the bearing plate play installation setting and rotate with the connecting axle and be connected regulation effect.

Preferably, the driving adjusting assembly comprises a chain, the chain is driven and adjusted by a driving gear and a driving motor, and the driving motor is arranged in a way of being connected with the limiting structure parts.

Through adopting above-mentioned technical scheme, thereby play drive adjustment and rotate spacing effect through driving motor.

Preferably, the connection limiting structure comprises a sleeve with a threaded hole, one side of the sleeve is provided with a connection plate arranged in a manner of being installed with the stress plate, and the other connection plate is provided with a supporting block through a connection rod.

Through adopting above-mentioned technical scheme, thereby through the screw hole with adjusting nut play threaded connection and atress relative regulation effect.

Preferably, the diameter ratio of the sleeve to the inner ring and the outer ring of the output end of the driving cylinder is 2:1.

through adopting above-mentioned technical scheme, thereby through the sleeve pipe play run through and set up with run through the installation setting effect.

Preferably, the whole shape of the stress plate is L-shaped.

Through adopting above-mentioned technical scheme, thereby through the atress board play atress drive and atress installation supporting effect.

Compared with the prior art, the utility model has the beneficial effects that: the X-ray detection device for multi-angle shooting detection,

(1) The driving adjustment assembly is arranged in the basic structure, so that the problem that the existing some electrified X-ray detection tools are solved, when parts are detected, the X-ray detection tools are turned over manually, the mode is very inconvenient in use, when the X-ray detector needs to be rotationally adjusted, the driving motor is controlled to work at the moment, the driven gear is driven to move by a chain in the working process of the driving motor, the driven gear is driven to rotationally adjust by a stress of the X-ray detector in the stress moving process of the driven gear through a connecting shaft, the situation is avoided by changing the driving angle of the X-ray detector, and the parts with different thicknesses and heights are sequentially and conveniently detected by controlling the driving cylinder to rotationally adjust the X-ray detector in the same direction and vertically;

(2) The base component is arranged in the foundation structure, so that the problem that the whole equipment cannot be moved and adjusted and the practical effect of the whole equipment is reduced is solved, when the whole equipment needs to be moved, an operator manually pushes the driving cylinder to work, the movable wheels are driven to move in the same direction in the stressed movement process of the driving cylinder, the whole equipment is driven to move in different working places to carry out detection work in the stressed movement process of the movable wheels, the base component is utilized to avoid the situation, and the damping shock absorber is utilized to play a role in buffering and shock absorption in the moving process of the whole equipment;

(3) Through the connection limit structure who sets up to solve the unable synchronous regulation's of driving motor condition, drive the cylinder and drive atress board syntropy atress motion through the sleeve pipe this moment in the driving cylinder course of working, drive driving motor synchronous atress motion through atress board atress motion in-process, through the synchronous condition that changes driving motor syntropy altitude distance not only avoids foretell condition but also avoids driving motor to cause driving gear and driven gear to cause the condition of relative pulling through the chain.

Drawings

FIG. 1 is a schematic diagram of a front cross-sectional structure of the present utility model;

FIG. 2 is a schematic diagram of the basic structure of the present utility model;

FIG. 3 is a schematic view of a base assembly of the present utility model;

FIG. 4 is a schematic view of a driving adjustment assembly according to the present utility model;

FIG. 5 is a schematic view of a connection limiting structure of the present utility model;

fig. 6 is a schematic view of the structure of the sleeve according to the present utility model.

In the figure: 1. the device comprises a base structure, 101, a base assembly, 1011, a mounting plate, 1012, a damping shock absorber, 1013, a movable wheel, 102, a driving adjusting assembly, 1021, a driving cylinder, 1022, a bearing plate, 1023, a connecting shaft, 1024, an X-ray detector, 1025, a driven gear, 1026, a chain, 1027, a driving gear, 1028, a driving motor, 2, a connecting limiting structure, 201, a sleeve, 202, a connecting plate, 203, a stress plate, 204 and a supporting block.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. 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.

Referring to fig. 1-6, the present utility model provides a technical solution: an X-ray detection device for multi-angle shooting detection is shown in fig. 1, 2, 3 and 4, and comprises a base structure 1 which is arranged on a connection limiting structure 2, wherein the base structure 1 comprises a base component 101 which is arranged on a driving adjusting component 102, the base component 101 comprises a mounting plate 1011 with a plurality of damping dampers 1012 at the bottom, movable wheels 1013 which move the whole device in different workplaces are arranged at the bottom of the mounting plate 1011 through the damping dampers 1012, 4 damping dampers 1012 and the movable wheels 1013 are symmetrically arranged, the symmetrically arranged parts are used for not only playing a stable stress supporting effect on the mounting plate 1011 but also playing an effective stress dispersion supporting effect on the parts which are arranged on the mounting plate 1011, and meanwhile, the parts are arranged by adopting the prior art structure, and the motion adjusting and motion buffering damping effects of the mounting plate 1011 are ensured when the prior art structure is sequentially arranged.

The above scheme is further, foundation structure 1 includes drive adjustment subassembly 102, drive adjustment subassembly 102 is equipped with the actuating cylinder 1021 of bearing plate 1022 including the top, actuating cylinder 1021 one side is equipped with the controller to spare part control adjustment, wherein, bearing plate 1022 and actuating cylinder 1021 are all provided with two to this, thereby utilize the spare part that the symmetry set up to play synchronous drive adjustment effect, and bearing plate 1022 adopts the bearing frame equi-structural setting with among the prior art structure, thereby utilize bearing plate 1022 to play supporting rotation adjustment effect to connecting axle 1023 one end.

The above scheme is further in proper order, and drive adjustment subassembly 102 includes bearing plate 1022, and bearing plate 1022 is equipped with X-ray detector 1024 through connecting axle 1023, and X-ray detector 1024 is equipped with the driven gear 1025 of being connected with the meshing of chain 1026 through connecting axle 1023, and wherein connecting axle 1023 is provided with two equally, utilizes two connecting axles 1023 that the symmetry set up not only to play the installation with X-ray detector 1024 both sides and sets up the effect still to play and hang the installation and drive the effect of adjusting to whole X-ray detector 1024.

The above scheme is still further, and drive adjustment subassembly 102 includes chain 1026, and chain 1026 passes through driving gear 1027 and driving motor 1028 drive regulation, and driving motor 1028 and connection limit structure 2 spare part installation setting, wherein, thereby the prior art structure setting is all taken to above-mentioned spare part, thereby plays drive adjustment and meshing when utilizing prior art structure to set up above-mentioned spare part and drives the connection effect.

In the above scheme, when the rotation direction of the X-ray detector 1024 needs to be adjusted, the controller is used to control the driving motor 1028 to work, the driving motor 1028 drives the chain 1026 to move through the driving gear 1027 in the working process, the driving shaft 1023 is driven to move through the driving gear 1027 in the working process of the chain 1026, the connecting shaft 1023 drives the X-ray detector 1024 to move in the same direction in the working process of the driving shaft 1023, when the X-ray detector 1024 is adjusted at a corresponding adjusting angle, the driving motor 1028 stops working, when the X-ray detector 1024 needs to be adjusted at a corresponding adjusting angle, the driving cylinder 1021 is controlled to work through the controller again, the driving cylinder 1021 drives the connecting shaft 1023 to move in the same direction in the working process of the driving cylinder 1021 through the bearing plate 1022, the connecting shaft 1023 also drives the X-ray detector 1024 to be adjusted in the working process of the driving cylinder 1021 in the working process of the driving shaft 1013, and the operator manually pushes the driving cylinder 1021 to move in the working process of other working places when the whole equipment needs to move in the working process of the working places, and the damper 1012 and the movable wheel 1013 are driven by the mounting plate 1011 in the working process of the whole equipment in the working process of the working place.

As shown in fig. 5 and 6, the connection limiting structure 2 includes a sleeve 201 with a threaded hole, and the diameter ratio of the sleeve 201 to the inner ring and the outer ring of the output end of the driving cylinder 1021 is 2:1, the diameter ratio of the inner ring to the outer ring is 2:1, not only the wrap connectivity of the inner ring of the sleeve 201 and the outer ring of the output end of the driving cylinder 1021 is shown, but also the mating connectivity and the penetrating connectivity between the two are shown, and the diameter ratio of the inner ring and the outer ring is 2:1, embody the above-mentioned two simultaneously and be concentric coaxial installation connectivity effect, embody the quick installation detachability effect between the above-mentioned two in proper order, sleeve 201 one side is equipped with the connecting plate 202 that sets up with atress board 203 installation, atress board 203 overall shape is "L" shape setting, so not only embody the two-way connectivity that above-mentioned structure set up, still embody the atress syntropy drivability effect that above-mentioned structure set up, and be "L" shape setting through above-mentioned structure overall shape, embody above-mentioned structure simultaneously to driving motor 1028 fixed mounting nature and atress supportive effect, and another connecting plate 202 is through being equipped with supporting piece 204.

In the above scheme, when the driving cylinder 1021 works, the connecting plate 202 is driven to move by force through the sleeve 201, and the connecting plate 202 drives the driving motor 1028 to move by force in the same direction through the force bearing plate 203, and the driving cylinder 1021 loosens the fixing nut on the other sleeve 201, so that the output end of the other driving cylinder 1021 and the other sleeve 201 move by force relatively, and when the whole device is adjusted, the fixing nut is adjusted again to enable the abutting block 204 to be in close contact with the ground, so that a static contact limiting effect is achieved on the whole device.

The terms "center," "longitudinal," "transverse," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used for descriptive simplicity and convenience only and not as an indication or implying that the apparatus or element being referred to must have a particular orientation, be constructed and operated for a particular orientation, based on the orientation or positional relationship illustrated in the drawings, and thus should not be construed as limiting the scope of the present utility model.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. The utility model provides an X-ray detection device that detection was shot to multi-angle, is including foundation structure (1) to connection limit structure (2) installation setting, its characterized in that: the foundation structure (1) comprises a base assembly (101) which is installed on the driving adjusting assembly (102), the base assembly (101) comprises a mounting plate (1011) with a plurality of damping shock absorbers (1012) at the bottom, and movable wheels (1013) which move the whole device at different workplaces are arranged at the bottom of the mounting plate (1011) through the damping shock absorbers (1012);

the foundation structure (1) comprises a driving adjusting assembly (102), the driving adjusting assembly (102) comprises a driving cylinder (1021) provided with a bearing plate (1022) above, and a controller for controlling and adjusting parts is arranged on one side of the driving cylinder (1021).

2. The X-ray detection apparatus for multi-angle shooting detection as claimed in claim 1, wherein: the drive adjusting assembly (102) comprises a bearing plate (1022), the bearing plate (1022) is provided with an X-ray detector (1024) through a connecting shaft (1023), and the X-ray detector (1024) is provided with a driven gear (1025) which is meshed and connected with a chain (1026) through the connecting shaft (1023).

3. The X-ray detection apparatus for multi-angle shooting detection as claimed in claim 2, wherein: the driving adjusting assembly (102) comprises a chain (1026), the chain (1026) is driven and adjusted by a driving gear (1027) and a driving motor (1028), and the driving motor (1028) is arranged in a way of being connected with parts of the limiting structure (2).

4. The X-ray detection apparatus for multi-angle shooting detection as claimed in claim 1, wherein: the connecting limiting structure (2) comprises a sleeve (201) with a threaded hole, one side of the sleeve (201) is provided with a connecting plate (202) which is arranged in a manner of being installed with a stress plate (203), and the other connecting plate (202) is provided with a supporting block (204) through a connecting rod.

5. The X-ray detection apparatus for multi-angle shooting detection as claimed in claim 4, wherein: the diameter ratio of the inner ring and the outer ring of the output end of the sleeve (201) to the output end of the driving cylinder (1021) is 2:1.

6. the X-ray detection apparatus for multi-angle shooting detection as claimed in claim 4, wherein: the whole shape of the stress plate (203) is L-shaped.