CN111970426A - Image processing equipment with telescopic structure based on computer - Google Patents

Abstract

The invention discloses an image processing device with a telescopic structure based on a computer, which comprises an upper end shell, a supporting base, an image acquisition component, a built-in conveying component and a light compensation component, wherein transmission ports are formed in two sides of the upper end shell, the image acquisition component is horizontally arranged on the upper side in the upper end shell, the image acquisition component is used for carrying out local precision scanning on a visible picture in the visual field range of the image acquisition component and effectively acquiring scanning data, and an image data collecting device is also arranged in the upper end shell and used for sorting and conveying scanned image information to the computer; the upper end face central point of supporting the base puts and is provided with built-in conveying subassembly, built-in conveying subassembly will wait to scan the picture template and transmit under the image acquisition subassembly, support the inside light compensation subassembly that still is equipped with of base, this light compensation subassembly is effectively to carrying out light illumination compensation inside the upper end casing.

Description

Image processing equipment with telescopic structure based on computer

Technical Field

The invention relates to the technical field of garlic processing equipment, in particular to computer-based image processing equipment with a telescopic structure.

Background

The digital image processing system is an equipment system for carrying out image digital processing and digital drawing thereof, and the digital image processing is a method and a technology for carrying out noise reduction, enhancement, restoration, segmentation, feature extraction and other processing on an image through a computer; common applications include detection and identification (many cameras include this function), video search, automotive assistance systems (e.g., pedestrian detection, traffic sign identification), and so on, which are currently in a fast growing phase; with the development of modern society, science and technology are continuously advanced, and the technology of computer image processing and digital drawing equipment systems is gradually mature and more perfect, but the equipment for processing image template information in the prior art cannot well acquire images in the image acquisition and identification process under the influence of the working environment of the equipment, and the specific defects of the equipment comprise image distortion, proportion imbalance, low acquisition precision and the like, and the equipment does not have local precise amplification on the image template in the identification process, so that the mirror surface of the image template is blurred in the focusing process, and therefore, the image processing equipment with the telescopic structure based on a computer is necessary to be provided to solve the problems.

Disclosure of Invention

In order to achieve the purpose, the invention provides the following technical scheme: an image processing device with a telescopic structure based on a computer comprises an upper end shell, a supporting base, an image acquisition component, a built-in conveying component and a light compensation component, wherein clamping grooves used for embedding and fixing the upper end shell are formed in two sides of the upper end face of the supporting base, the upper end shell is fixed on the supporting base through bolts at the outer edge of a shell of the upper end shell, transmission ports are formed in two sides of the upper end shell and used for feeding or taking out a picture template to be scanned, driving wheels are symmetrically arranged at four corners of the lower end face of the supporting base, the image acquisition component is horizontally arranged on the upper side in the upper end shell,

the image acquisition assembly scans the local precision of the visible picture in the visual field range of the image acquisition assembly and effectively acquires the scanning data, and the upper end shell is internally provided with an image data collection device which arranges and transmits the scanned image information to a computer;

the image scanning device comprises a supporting base, an image acquisition assembly, a built-in conveying assembly and a control assembly, wherein the center of the upper end surface of the supporting base is provided with the built-in conveying assembly, the built-in conveying assembly conveys a picture template to be scanned to the position under the image acquisition assembly, and the acquisition surface of the picture template is subjected to local leveling treatment, so that the image acquisition assembly can completely scan details of the picture template in the scanning process;

support the inside light compensation subassembly that still is equipped with of base, should light compensation subassembly effectively carries out light illumination compensation to the upper end casing is inside.

As a preferred technical scheme of the present invention, the image capturing assembly includes a central guide rod, a fixed frame, an internal thread shaft and a scanning device, wherein the fixed frame is symmetrically arranged on the left and right of the upper side inside the upper end housing, the fixed frame is fixedly arranged inside the upper end housing through a fixing member, the internal thread shaft is longitudinally connected in the fixed frame in a relatively rotatable manner, a rotating motor is installed outside the fixed frame, and an output end of the rotating motor is connected and fixed with the internal thread shaft and drives the internal thread shaft to make a constant speed rotation movement;

a central guide rod is transversely arranged between the fixed frames in a relatively sliding manner, and two sections of the central guide rod are connected with the internal thread shaft for transmission through a thread meshing effect, so that the central guide rod longitudinally translates along the internal thread shaft;

the central guide rod is provided with a scanning device in a sliding mode, the scanning device is connected with the image data collecting device through a connecting lead, and the image scanning data are transmitted in time.

As a preferred technical scheme of the invention, the scanning device comprises a bearing disc, a sliding seat, a scanning probe, an electric telescopic rod, a telescopic sleeve rod and a guide sleeve, wherein the sliding seat is arranged on the central guide rod in a relatively sliding manner and driven by a built-in driving wheel shaft, the guide sleeve is vertically fixed on the lower end surface of the sliding seat and is of a multi-section telescopic structure,

the other end of the guide sleeve is provided with a bearing disc, an electric telescopic rod is coaxially arranged in the guide sleeve, one end of the electric telescopic rod is connected with the sliding seat, the output end of the electric telescopic rod is fixed with the bearing disc, and the relative height of the vertical surface of the bearing disc is adjusted through the telescopic action of the electric telescopic rod;

mounting notches for limiting and mounting the scanning probe are formed in the two sides of the lower end face of the bearing plate, and the scanning probe can be arranged in the mounting notches in a relatively rotating mode;

one side of the guide sleeve, which is close to the sliding seat, is symmetrically hinged with telescopic sleeve rods, the other end of each telescopic sleeve rod is rotatably connected with the bearing plate, a driven gear is fixed at the shaft core of the scanning probe, and a driving gear is fixed at one end of each telescopic sleeve rod, so that the scanning probe is in meshing transmission with the telescopic sleeve rods through the gear meshing effect;

the scanning probe is also sleeved with a protective cover.

As a preferable technical scheme of the invention, the built-in conveying assembly comprises an installation seat, a main supporting plate, an auxiliary adsorption piece and a micro pumping pump, wherein the installation seat is fixedly embedded in the upper end surface of the supporting base, the main supporting plate is horizontally paved in the installation seat and used for positioning and supporting the picture template through the main supporting plate,

evenly be provided with a plurality of supplementary absorption pieces in the main backup pad, just install miniature pump in the support base, miniature pump through connecting tube with supplementary absorption piece is linked together, each supplementary absorption piece is fixed to picture template regional scope absorption formula for the picture template closely laminate in on the main backup pad.

As a preferred technical solution of the present invention, an upper connecting plate is further fixed on the upper end surface of the mounting seat, the upper connecting plate and the main supporting plate are matched with each other to form a limiting space, a plurality of top pressure friction members arranged at intervals with the auxiliary adsorbing member are arranged on the lower end surface of the upper connecting plate, and the top pressure friction members perform effective leveling processing on the end surface of the image template when the image template is transferred onto the main supporting plate.

As a preferable technical scheme of the invention, two sides of the upper end surface of the supporting base are symmetrically and relatively rotatably provided with fixed guide wheels, and the corresponding position of the upper end shell is relatively rotatably provided with an auxiliary driving wheel which is mutually matched with the fixed guide wheels for transmission.

As a preferred technical scheme of the invention, the light compensation component comprises a light-transmitting plate, an external fixing piece, a high-frequency light source, an arc-shaped bracket and a reflecting piece, wherein a built-in cavity for installing the light-transmitting plate is arranged in the supporting base, two ends of the light-transmitting plate are respectively and transversely fixed in the supporting base through the external fixing piece, the arc-shaped bracket is arranged on the lower end surface of the supporting base,

high-frequency light sources are obliquely arranged on two sides of the light-transmitting plate, provide illumination light and locally irradiate the image template through the light-transmitting plate;

the arc-shaped support can be provided with a light reflecting piece in a relatively sliding mode, and the light reflecting piece conducts directional reflection on light source rays of the high-frequency light source.

As a preferred technical solution of the present invention, the reflector further includes a reflector plate, a connection supporting plate, a lower fixing member, a retractable guide rod, and a driving seat, the lower fixing member is slidably disposed on the arc-shaped bracket, the upper end surface of the lower fixing member is fixed with the connection supporting plate through the retractable guide rod, the reflector plate is mounted on a side of the connection supporting plate away from the lower fixing member, and light is reflected by the reflector plate;

a guide rod is further arranged between the connecting supporting plate and the lower fixing piece, and one end of the guide rod is rotatably connected with the connecting supporting plate through a rotary sphere, so that the connecting supporting plate can be rotatably adjusted relative to the lower fixing piece within a certain range;

and the lower fixing piece is also provided with a driving seat.

Compared with the prior art, the invention provides the image processing equipment with the telescopic structure based on the computer, which has the following beneficial effects:

in the invention, an upper end shell is arranged on a supporting base, so that an environment space for image acquisition is formed in the supporting base, a picture template is conveyed to the position under an image acquisition assembly through a built-in conveying assembly, and the image acquisition assembly carries out local scanning and data acquisition, wherein a plurality of auxiliary adsorption pieces are uniformly distributed on a main supporting plate in order to keep the smoothness of the picture template, the picture template is adsorbed and fixed on the main supporting plate by utilizing the auxiliary adsorption pieces, and residual airflow between the picture template and the main supporting plate can be discharged, so that the picture template is completely attached to the main supporting plate after being flattened by a jacking friction piece, the picture template is convenient to carry out image acquisition, and a light compensation assembly is also arranged in the supporting base, the light compensation assembly reflects light rays through a reflecting piece through a high-frequency light source to form a light supplement area, on one hand, the high-frequency light source can be effectively prevented from directly irradiating, lead to its printing opacity phenomenon to appear, on the other hand can effectively enlarge its scattering scope via reflection of light spare reflection, improves the light filling effect to, in the image acquisition process, scanning probe accessible electric telescopic handle carries out the adjustment of perpendicular height, makes it can carry out controllable adaptation regulation according to picture template discernment degree, and it still can change the horizontal plane through gear engagement and shoot the angle when adjusting, so that adapt to image template size of a dimension.

Drawings

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

FIG. 2 is a schematic structural diagram of an image capturing assembly according to the present invention;

FIG. 3 is a schematic view of a scanning device according to the present invention;

FIG. 4 is a schematic view of the built-in conveyor assembly of the present invention;

FIG. 5 is a schematic structural diagram of a lamp light compensation assembly according to the present invention;

FIG. 6 is an enlarged view of the point A in FIG. 5;

in the figure: 1 upper end shell, 2 supporting base, 201 driving wheel, 3 image data collecting device, 4 image collecting component, 401 internal thread shaft, 402 fixing component, 403 connecting lead, 404 central guide rod, 405 fixing frame, 5 built-in conveying component, 501 mounting seat, 502 main supporting plate, 503 auxiliary adsorption component, 504 micro pumping pump, 505 connecting conduit, 506 upper connecting plate, 507 top pressure friction component, 508 fixing guide wheel, 509 auxiliary driving wheel, 6 light compensation component, 601 light transmission plate component, 602 arc bracket, 603 external fixing component, 604 high frequency light source, 7 scanning device, 701 bearing disc, 702 scanning probe, 703 electric telescopic rod, 704 sliding seat, 705 guide sleeve, 706 driven gear, 707 telescopic sleeve rod, 708 protective cover, 8 light reflection component, 801 lower fixing component, 802 connecting supporting plate, 803 reflecting mirror plate, 804 telescopic guide rod, 805 guide rod, 806 driving seat.

Detailed Description

Referring to fig. 1, the present invention provides a technical solution: an image processing device with a telescopic structure based on a computer comprises an upper end shell 1, a supporting base 2, an image acquisition component 4, a built-in conveying component 5 and a light compensation component 6, wherein clamping grooves for embedding and fixing the upper end shell 1 are formed in two sides of the upper end surface of the supporting base 2, the upper end shell 1 is fixed on the supporting base 2 through bolts at the outer edge of a shell of the upper end shell 1, transmission ports are formed in two sides of the upper end shell 1 and used for feeding or taking out a picture template to be scanned, driving wheels 201 are symmetrically arranged at four corners of the lower end surface of the supporting base 2, the image acquisition component 4 is horizontally arranged on the upper side in the upper end shell 1,

the image acquisition assembly 4 is used for carrying out local precision scanning on a visual picture in a visual field range and effectively acquiring scanning data, the upper end shell 1 is also internally provided with an image data collection device 3, and the image data collection device 3 is used for arranging and conveying scanned image information to a computer;

a built-in conveying assembly 5 is arranged at the center of the upper end face of the supporting base 2, the built-in conveying assembly 5 conveys the picture template to be scanned to the position under the image acquisition assembly 4, and local leveling processing is carried out on the acquisition face of the picture template, so that the image acquisition assembly 4 can completely scan details of the picture template in the scanning process;

support 2 insides and still be equipped with light compensation subassembly 6, should light compensation subassembly 6 effectively carries out light illumination compensation to the upper end casing is inside, and here, light compensation subassembly assists from image template below and shines for it can form lighting system to image template, and it needs to be noted that, in order to ensure that light luminance keeps unanimous, should support the environment space that base and upper end casing formed and be in little encapsulated situation, improve the light compensation effect.

Referring to fig. 2, in this embodiment, the image capturing assembly 4 includes a central guide rod 404, a fixing frame 405, an internal thread shaft 401 and a scanning device 7, wherein the fixing frame 405 is symmetrically arranged on the upper side of the inside of the upper housing 1, the fixing frame 405 is externally fixed in the upper housing 1 through a fixing member 402, the internal thread shaft 401 is longitudinally connected in the fixing frame 405 in a relatively rotatable manner, a rotating motor (not shown in the figure) is installed outside the fixing frame 405, and an output end of the rotating motor is connected and fixed to the internal thread shaft 401 and drives the internal thread shaft 401 to perform a constant speed rotation;

a central guide rod 404 is transversely arranged between the fixed frames 405 in a relatively sliding manner, and two sections of the central guide rod 404 are connected with the internal thread shaft 401 through a thread meshing effect for transmission, so that the central guide rod 404 longitudinally translates along the internal thread shaft 401;

the central guide rod 404 is provided with a scanning device 7 in a sliding manner, the scanning device 7 is connected with an image data collecting device through a connecting lead 403, image scanning data is transmitted in time, and the central guide rod is controlled to longitudinally translate through the thread engagement of the internal thread shaft, so that the scanning device can conveniently longitudinally scan, and the scanning device has high stability.

Referring to fig. 3, in this embodiment, the scanning device 7 includes a carrier plate 701, a sliding seat 704, a scanning probe 702, an electric telescopic rod 703, a telescopic sleeve rod 707, and a guide sleeve 705, wherein the sliding seat 704 is disposed on the central guide rod 404 in a relatively slidable manner, the sliding seat 704 is driven by an internal drive axle, the guide sleeve 705 is vertically fixed on a lower end surface of the sliding seat 704, the guide sleeve 705 is in a multi-stage telescopic structure,

the other end of the guide sleeve 705 is provided with a bearing disc 701, an electric telescopic rod 703 is coaxially arranged in the guide sleeve 705, one end of the electric telescopic rod 703 is connected with a sliding seat 704, the output end of the electric telescopic rod 703 is fixed with the bearing disc 701, and the vertical plane relative height of the bearing disc 701 is adjusted through the telescopic action of the electric telescopic rod 703;

mounting notches for limiting and mounting the scanning probe 702 are formed in two sides of the lower end face of the bearing plate 701, and the scanning probe 702 can be relatively rotatably arranged in the mounting notches;

telescopic sleeve rods 707 are symmetrically hinged to one side, close to the sliding seat 704, of the guide sleeve 705, the other end of each telescopic sleeve rod 707 is rotatably connected with the bearing disc 701, a driven gear 706 is fixed at the shaft core of the scanning probe 702, and a driving gear is fixed at one end of each telescopic sleeve rod 707, so that the scanning probe 702 is in meshing transmission with the telescopic sleeve rods 707 through a gear meshing effect;

the scanning probe 702 is sleeved with a protective cover 708, wherein when the electric telescopic rod controls the bearing disc to move downwards, the effective distance between the scanning probe and the picture template is reduced, and the telescopic sleeve rod controls the scanning probe to rotate inwards to adjust through the meshing action of gears, so that the data acquisition effect of locally amplifying the picture template is achieved; when electronic telescopic link control bears the dish upward movement, the effective interval grow between scanning probe and the picture template, and flexible loop bar passes through the external rotation regulation of gear engagement control scanning probe to scanning probe can carry out data acquisition to image template is whole, has higher discernment adjustment nature.

Referring to fig. 4, in the present embodiment, the built-in conveying assembly 5 includes a mounting seat 501, a main supporting plate 502, an auxiliary absorbing member 503, and a micro-pumping pump 504, wherein the mounting seat 501 is fixed in the upper end face of the supporting base 2, the main supporting plate 502 is horizontally laid in the mounting seat 501, and the picture template is positioned and supported by the main supporting plate 502,

evenly be provided with a plurality of supplementary absorption pieces 503 in the main fagging 502, just install miniature pump 504 in the support base 2, miniature pump 501 through connecting tube 505 with supplementary absorption piece 503 is linked together, each supplementary absorption piece 503 is fixed to picture template region scope absorption formula for the picture template closely laminate in on the main fagging 502.

In this embodiment, an upper connecting plate 506 is further fixed on the upper end surface of the mounting seat 501, the upper connecting plate 506 and the main supporting plate 502 are matched with each other to form a limiting space, a plurality of jacking friction members 507 arranged at intervals with the auxiliary adsorption members 503 are arranged on the lower end surface of the upper connecting plate 506, and the jacking friction members 507 perform effective leveling processing on the end surfaces of the image templates when the image templates are transmitted to the main supporting plate.

In this embodiment, the two sides of the upper end surface of the supporting base 2 are symmetrically provided with fixed guide wheels 508 capable of rotating relatively, and the corresponding position of the upper end casing 1 is provided with an auxiliary driving wheel 509 capable of rotating relatively, and the auxiliary driving wheel 509 and the fixed guide wheels 508 are in transmission in a matching manner.

Referring to fig. 5, in the present embodiment, the lamp light compensation assembly 6 includes a transparent plate 601, an external fixing member 603, a high-frequency light source 604, an arc-shaped bracket 602, and a light reflecting member 8, wherein a built-in cavity for installing the transparent plate 601 is disposed in the supporting base 2, two ends of the transparent plate 601 are respectively fixed in the supporting base 2 transversely by the external fixing member 603, the arc-shaped bracket 602 is disposed on a lower end surface of the supporting base 2,

moreover, high-frequency light sources 604 are obliquely arranged on both sides of the light-transmitting plate 601, and the high-frequency light sources 604 provide illumination light and locally irradiate the image template through the light-transmitting plate 601;

but the relatively gliding is provided with reflector 8 on the arc support 602, reflector 8 carries out the directional reflection to the light source ray of high frequency light source 604, and here, for avoiding high frequency light source direct irradiation picture template to produce the printing opacity phenomenon, carries out the light reflection through reflector, and can effectively enlarge its scattering scope, improves the light filling effect.

Referring to fig. 6, in this embodiment, the reflector 8 further includes a mirror plate 803, a connection supporting plate 802, a lower fixture 801, a retractable guide rod 804, and a driving seat 806, the lower fixture 801 is slidably disposed on the arc-shaped bracket 602, the connection supporting plate 802 is fixed to the upper end surface of the lower fixture 801 through the retractable guide rod 804, the mirror plate 803 is mounted on a side of the connection supporting plate 802 away from the lower fixture 801, and light is reflected by the mirror plate 803;

a guide bar 805 is further arranged between the connecting supporting plate 802 and the lower fixing member 801, and one end of the guide bar 805 is rotatably connected with the connecting supporting plate 802 through a rotary sphere, so that the connecting supporting plate 802 can be rotatably adjusted relative to the lower fixing member 801 within a certain range;

the lower fixture 801 is further provided with a driving seat 806, which can effectively adjust the reflection angle of the mirror plate, so that light can correspondingly illuminate the image acquisition range.

Specifically, when data acquisition is carried out on the image template, the image template enters the interior of the device through a transmission port on one side of the upper end shell, the image template is transmitted to the main supporting plate through the mutually matched transmission between the auxiliary transmission wheel and the fixed guide wheel, when the image template is located under the image acquisition assembly completely in term, residual airflow between the image template and the main supporting plate is exhausted by using the auxiliary adsorption piece, the image template is adsorbed and fixed on the main supporting plate, the transverse displacement distance of the scanning probe is adjusted through the sliding seat, and the central guide rod is controlled to carry out longitudinal translation through the thread meshing of the internal thread shaft, so that the scanning device carries out longitudinal scanning.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can substitute or change the technical solution of the present invention and the inventive concept within the technical scope of the present invention, and the technical solution and the inventive concept thereof should be covered by the scope of the present invention.

Claims (8)

1. The utility model provides an image processing equipment with extending structure based on computer, its includes upper end casing (1), supports base (2), image acquisition subassembly (4), built-in conveyor components (5) and light compensation subassembly (6), wherein, the up end both sides of supporting base (2) all are equipped with and are used for the embedding to fix the joint recess of upper end casing (1), upper end casing (1) is fixed on supporting base (2) along the bolt through its casing outer border, the both sides of upper end casing (1) all are equipped with the transmission mouth for send into or take out and wait to scan the picture template, the lower terminal surface four corners position symmetry that supports base (2) is equipped with drive wheel (201), its characterized in that: an image acquisition component (4) is horizontally arranged at the upper side in the upper end shell (1),

the image acquisition assembly (4) is used for carrying out local precision scanning on a visual picture in a visual field range of the image acquisition assembly and effectively acquiring scanning data, an image data collection device (3) is further installed in the upper end shell (1), and the image data collection device (3) is used for arranging and conveying scanned image information to a computer;

a built-in conveying assembly (5) is arranged at the center of the upper end face of the supporting base (2), the built-in conveying assembly (5) conveys the picture template to be scanned to the position under the image acquisition assembly (4), and local leveling processing is carried out on the acquisition surface of the picture template, so that the image acquisition assembly (4) can completely scan all details of the picture template in the scanning process;

support base (2) inside still to be equipped with light compensation subassembly (6), should light compensation subassembly (6) effectively carry out light illumination compensation to upper end casing inside.

2. The computer-based image processing apparatus with a telescopic structure according to claim 1, wherein: the image acquisition assembly (4) comprises a central guide rod (404), a fixed frame (405), an internal thread shaft (401) and a scanning device (7), wherein the fixed frame (405) is symmetrically arranged on the left and right sides of the upper side inside the upper end shell (1), the fixed frame (405) is fixedly arranged in the upper end shell (1) through a fixing piece (402), the internal thread shaft (401) is longitudinally connected in the fixed frame (405) in a relatively rotating mode, a rotating motor is installed outside the fixed frame (405), and the output end of the rotating motor is connected and fixed with the internal thread shaft (401) and drives the internal thread shaft (401) to rotate at a constant speed;

a central guide rod (404) is transversely arranged between the fixed frames (405) in a relatively sliding manner, and two sections of the central guide rod (404) are connected with the internal thread shaft (401) for transmission through a thread meshing effect, so that the central guide rod (404) longitudinally translates along the internal thread shaft (401);

the central guide rod (404) is provided with a scanning device (7) in a sliding way, and the scanning device (7) is connected with an image data collecting device through a connecting lead (403) and transmits the scanning data of the picture in time.

3. The computer-based image processing apparatus with a telescopic structure according to claim 2, wherein: the scanning device (7) comprises a bearing disc (701), a sliding seat (704), a scanning probe (702), an electric telescopic rod (703), a telescopic sleeve rod (707) and a guide sleeve (705), wherein the sliding seat (704) is arranged on the central guide rod (404) in a relatively sliding manner, the sliding seat (704) is driven by a built-in driving wheel shaft, the guide sleeve (705) is vertically fixed on the lower end surface of the sliding seat (704), and the guide sleeve (705) is of a multi-section telescopic structure,

the other end of the guide sleeve (705) is provided with a bearing disc (701), an electric telescopic rod (703) is coaxially arranged in the guide sleeve (705), one end of the electric telescopic rod (703) is connected with the sliding seat (704), the output end of the electric telescopic rod is fixed with the bearing disc (701), and the vertical plane relative height of the bearing disc (701) is adjusted through the telescopic action of the electric telescopic rod;

mounting notches for limiting and mounting the scanning probe (702) are formed in two sides of the lower end face of the bearing disc (701), and the scanning probe (702) can be arranged in the mounting notches in a relatively rotating mode;

one side of the guide sleeve (705) close to the sliding seat (704) is symmetrically hinged with telescopic sleeve rods (707), the other end of each telescopic sleeve rod (707) is rotatably connected with the bearing disc (701), a driven gear (706) is fixed at the shaft core of the scanning probe (702), and a driving gear is fixed at one end of each telescopic sleeve rod (707) so that the scanning probe (702) is in meshing transmission with the telescopic sleeve rods (707) through the gear meshing effect;

the scanning probe (702) is sleeved with a protective cover (708).

4. The computer-based image processing apparatus with a telescopic structure according to claim 1, wherein: the built-in conveying assembly (5) comprises an installation seat (501), a main supporting plate (502), an auxiliary adsorption piece (503) and a micro pumping pump (504), wherein the installation seat (501) is fixedly embedded in the upper end face of the supporting base (2), the main supporting plate (502) is transversely paved in the installation seat (501), and the picture template is positioned and supported through the main supporting plate (502),

evenly be provided with a plurality of supplementary absorption pieces (503) in the main fagging (502), just install miniature pump (504) in supporting base (2), miniature pump (501) through connecting tube (505) with supplementary absorption piece (503) are linked together, each supplementary absorption piece (503) are fixed to picture template region scope absorption formula for picture template closely laminate in on main fagging (502).

5. The computer-based image processing apparatus with a telescopic structure according to claim 4, wherein: the upper end face of the mounting seat (501) is further fixed with an upper connecting plate (506), the upper connecting plate (506) and the main supporting plate (502) are matched with each other to form a limiting space, the lower end face of the upper connecting plate (506) is provided with a plurality of jacking friction pieces (507) which are arranged at intervals with the auxiliary adsorption pieces (503), and the jacking friction pieces (507) effectively level the end faces of the image templates when the image templates are transmitted to the main supporting plate.

6. The computer-based image processing apparatus with a telescopic structure according to claim 5, wherein: fixed guide wheels (508) are symmetrically and relatively rotatably arranged on two sides of the upper end face of the supporting base (2), auxiliary driving wheels (509) are relatively rotatably arranged at corresponding positions of the upper end shell (1), and the auxiliary driving wheels (509) are matched with the fixed guide wheels (508) for transmission.

7. The computer-based image processing apparatus with a telescopic structure according to claim 1, wherein: the lamplight compensation component (6) comprises a light-transmitting plate (601), an outer fixing piece (603), a high-frequency light source (604), an arc-shaped support (602) and a light reflecting piece (8), wherein a built-in cavity for installing the light-transmitting plate (601) is arranged in the supporting base (2), two ends of the light-transmitting plate (601) are respectively and transversely fixed in the supporting base (2) through the outer fixing piece (603), the arc-shaped support (602) is arranged on the lower end face of the supporting base (2),

high-frequency light sources (604) are obliquely arranged on two sides of the light-transmitting plate (601), and the high-frequency light sources (604) provide illumination light and locally irradiate the image template through the light-transmitting plate (601);

the arc-shaped support (602) is provided with a reflector (8) in a relatively sliding manner, and the reflector (8) performs directional reflection on the light source ray of the high-frequency light source (604).

8. The computer-based image processing apparatus with a telescopic structure according to claim 7, wherein: the reflector (8) further comprises a reflector plate (803), a connecting support plate (802), a lower fixing piece (801), a telescopic guide rod (804) and a driving seat (806), wherein the lower fixing piece (801) can be arranged on the arc-shaped support (602) in a relatively sliding mode, the upper end face of the lower fixing piece (801) is fixedly provided with the connecting support plate (802) through the telescopic guide rod (804), one side, far away from the lower fixing piece (801), of the connecting support plate (802) is provided with the reflector plate (803), and light reflection is carried out through the reflector plate (803);

a guide rod (805) is further arranged between the connecting supporting plate (802) and the lower fixing piece (801), and one end of the guide rod (805) is rotatably connected with the connecting supporting plate (802) through a rotary sphere, so that the connecting supporting plate (802) can be rotatably adjusted relative to the lower fixing piece (801) within a certain range;

and the lower fixing piece (801) is also provided with a driving seat (806).

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