CN113240572B - Photoelectric image processing device based on big data and implementation method thereof - Google Patents

Abstract

The invention relates to a photoelectric image processing device based on big data and an implementation method thereof, wherein the photoelectric image processing device based on big data comprises an embedded controller equipment shell and a USB plug, a chute is formed in the embedded controller equipment shell, a bearing plate is connected in the chute in a sliding manner, the top of the bearing plate is fixedly connected with a bearing shell, the bottom end of the inside of the bearing shell is provided with a chip connecting equipment shell, a transmission chip is arranged in the chip connecting equipment shell, the top of the transmission chip is provided with a rubber gasket, the top of the rubber gasket is provided with a chip cover plate, the top of the chip cover plate is fixedly connected with a transparent equipment shell, and balls are arranged in the transparent equipment shell; the side of embedded controller equipment shell is provided with the connection cardboard, is provided with the USB interface with the grafting cooperation of USB plug on the connection cardboard. The device and the implementation method thereof can ensure the flatness of chip installation and facilitate direct and accurate insertion of the USB interface.

Description

Photoelectric image processing device based on big data and implementation method thereof

Technical Field

The invention relates to the technical field of photoelectric image processing, in particular to a photoelectric image processing device based on big data and an implementation method thereof.

Background

The photoelectric image processing means that a computer system acquires an image and processes an original image through an optical system and a photoelectric image sensor, converts an analog image in the nature into a digital image in the computer, and further processes and analyzes the image, so that the image has a better visual effect or can meet specific requirements of certain applications, and the photoelectric image processing method is widely applied to the fields of geographic exploration, military affairs and the like.

The existing photoelectric image processing equipment transmits stored data through an embedded controller, the embedded controller also needs to replace and upgrade an internal chip along with the increase of the demand of a user, the chip replacing process is small in size, one corner tilting phenomenon easily occurs in the replacing process, naked eyes cannot directly see differences, but the transmission process is interrupted, meanwhile, the embedded controller is fixed inside a machine in a bolt fixing mode, a USB data line is not easily correctly inserted into an interface at the first time during data connection transmission, the direction of the USB data line needs to be continuously rotated to adjust so that the interface of the USB data line is aligned with the interface of the equipment, and the operation is inconvenient.

Disclosure of Invention

The invention provides a photoelectric image processing device based on big data and an implementation method thereof, aiming at the defects of the prior art.

The invention provides the following technical scheme: a photoelectric image processing device based on big data comprises an embedded controller device shell and a USB plug, wherein a sliding groove is formed in the embedded controller device shell, a bearing plate is connected to the inside of the sliding groove in a sliding mode, the top of the bearing plate is fixedly connected with a bearing shell, a chip connecting device shell is arranged at the bottom end of the inside of the bearing shell, a transmission chip is arranged in the chip connecting device shell, a rubber gasket is arranged at the top of the transmission chip, a chip cover plate is arranged at the top of the rubber gasket, a transparent device shell is fixedly connected to the top of the chip cover plate, and balls are arranged in the transparent device shell; the side of embedded controller equipment shell is provided with the connection cardboard, be provided with on the connection cardboard with the USB plug complex USB interface of pegging graft, be fixed with first magnet and second magnet on connection cardboard and the USB plug respectively, the polarity of first magnet and second magnet looks remote site is opposite, the one end fixed mounting who keeps away from the connection cardboard in the USB plug has the second to rotate the lasso, the surface that the second rotated the lasso evenly links firmly the polylith and connects the square, and the outside of each connection square links firmly first rotation lasso jointly, the surface activity of first rotation lasso has cup jointed and has held the lasso, hold lasso, first rotation lasso and second rotation lasso and set up with one heart, one section bottom that lies in between second magnet and the second rotation lasso in the USB plug has linked firmly the counter weight square, the weight of counter weight square is greater than the weight of USB plug, the both ends face of holding the lasso has linked firmly respectively with first rotation lasso complex spacing square.

Preferably, a fastening nut is arranged on the surface of the chip cover plate, and the chip cover plate is connected with the chip connecting equipment shell through the fastening nut.

Preferably, the double-phase offside that bears the weight of the shell inner wall has linked firmly telescopic tube respectively, two telescopic tube's inside symmetry sliding connection has the telescopic link, is provided with the connecting plate between the opposite side of two telescopic links, the both ends of connecting plate have linked firmly the connecting rod respectively, the connecting rod passes through the bearing and is connected with the telescopic link rotation, the side of connecting plate has linked firmly spacing cover shell, the periphery of chip apron links firmly with the inner wall bottom of spacing cover shell.

Preferably, the both sides of embedded controller equipment shell are all fixed mounting have an extension curb plate, the catching groove has been seted up to the side of extending the curb plate, the inside joint of catching groove has the lock joint piece, the fixed joint in side of lock joint piece has the joint bearing block, the top fixed mounting of joint bearing block has dustproof ceiling.

Preferably, the side surface of the chip connection device shell is provided with an exhaust hole, and the surface of the embedded controller device shell is provided with a radiating fin.

The invention also provides an implementation method of the photoelectric image processing device based on the big data, which comprises the following steps:

s1, detaching the connecting clamping plate from the embedded controller equipment shell, and sliding the connecting clamping plate out of the bearing shell above the bearing plate from the inside of the sliding groove;

s2, rotating a connecting plate, driving the limiting sleeve to rise by the connecting plate, and replacing the chip;

s3, after the chip is replaced, if the ball is in the middle of the transparent equipment shell and is stable and immobile, the chip is flat, the chip is replaced, and the step S5 is carried out; if the ball rolls in the transparent equipment shell, the chip is not flat, and the step S4 is carried out;

s4, rolling the ball in the transparent equipment shell from the high end of the chip to the low end of the chip, adjusting a fastening nut corresponding to the high end until the ball is in the middle of the transparent equipment shell and is stable and immobile, and then leveling the chip;

s5, during USB connection, the USB plug is always kept in the correct insertion direction under the action of the counterweight square block, and the correct insertion of the USB plug can be assisted through mutual adsorption of the second magnet and the first magnet, so that the accurate and quick insertion operation of the USB plug is realized;

and S6, clamping the fastening block of the plastic clamping bearing block with the fastening groove of the extending side plate, and performing dustproof protection on the radiating fin through a dustproof ceiling at the top.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the photoelectric image processing device based on the big data and the implementation method thereof, the ball, the transparent equipment shell and the fastening nut are arranged, after the chip is replaced, if the ball is in the middle of the transparent equipment shell and is stable and fixed, the chip is flat, if the ball rolls in the transparent equipment shell, the chip is uneven, the ball rolls from the high end of the chip to the low end in the transparent equipment shell, the fastening nut corresponding to the high end is adjusted until the ball rolls back to the middle of the transparent equipment shell and is stable and fixed, the problem that an embedded controller of the photoelectric image processing equipment is prone to tilting at one corner in the replacement process to cause discontinuity in the data transmission process is effectively solved, and the flatness of the replacement chip is ensured;

2. according to the photoelectric image processing device based on the big data and the implementation method thereof, the first magnet, the second magnet and the counterweight square block are arranged, when USB connection is needed, because the weight of the counterweight square block is greater than that of a USB plug, the second rotating ferrule on the side surface of the USB plug is controlled to drive the first rotating ferrule on the side surface of the surface connection square block to rotate inside the holding ferrule, so that the USB plug is always in a correct inserting direction along with the counterweight square block, and then the first magnet and the second magnet are mutually adsorbed, so that the inserting process can be assisted, quick inserting is realized, the problem that a USB data line cannot be correctly inserted into a USB interface at the first time during data transmission is effectively solved, and misoperation is avoided;

3. in the photoelectric image processing device based on the big data and the implementation method thereof, by arranging the fastening groove, the fastening block and the dustproof ceiling, the dustproof ceiling can protect the radiating fins on the surface of the device in a dustproof manner, dust is prevented from entering the radiating fins and being difficult to clean, and meanwhile, when the dustproof ceiling needs to be cleaned regularly, the plastic fastening bearing blocks are pulled to two sides forcibly, so that the fastening block fixedly installed on the fastening bearing blocks is moved out from the fastening groove of the extending side plate, the dustproof ceiling is taken down to be cleaned, the problem that gaps among the radiating fins are easy to enter the dust and difficult to clean, and the overall heat dissipation performance is influenced is solved, and the effect that the dust influences the radiating fins is avoided.

Drawings

FIG. 1 is a schematic structural diagram of a big data-based electro-optical image processing apparatus according to the present invention;

FIG. 2 is a schematic diagram of a partial structure of a big data-based optoelectronic image processing apparatus according to the present invention;

FIG. 3 is a schematic diagram of an internal structure of an embedded controller device case of the optoelectronic image processing apparatus based on big data according to the present invention;

FIG. 4 is an enlarged view of point A in FIG. 1;

fig. 5 is an enlarged view of point B in fig. 3.

In the figure: 1. an embedded controller device housing; 2. connecting a clamping plate; 3. a chute; 4. a bearing plate; 5. a USB interface; 6. a load-bearing housing; 7. a connecting plate; 9. a telescopic sleeve; 10. a telescopic rod; 11. a connecting rod; 12. the chip is connected with the equipment shell; 13. a first magnet; 14. a USB plug; 15. the ferrule is gripped; 16. a first rotating collar; 17. connecting the squares; 18. a second rotating collar; 19. a limiting square block; 20. a counterweight block; 21. a second magnet; 22. a limiting casing; 23. fastening a nut; 24. a ball bearing; 25. a transparent device housing; 26. a chip cover plate; 27. a rubber gasket; 28. a transmission chip; 29. clamping the bearing block; 30. an extension side plate; 31. a dustproof ceiling; 32. buckling grooves; 33. a buckling block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

The utility model provides a photoelectric image processing apparatus based on big data, as shown in the figure, including embedded controller equipment shell 1 and USB plug 14, spout 3 has been seted up to embedded controller equipment shell 1's inside, the inside sliding connection of spout 3 has bearing plate 4, bearing plate 4's top has linked firmly bears shell 6, the bottom that bears shell 6 inside is provided with chip jointing equipment shell 12, the inside of chip jointing equipment shell 12 is provided with transmission chip 28, transmission chip 28's top is provided with rubber gasket 27, rubber gasket 27's top is provided with chip cover plate 26, transparent equipment shell 25 has been linked firmly at chip cover plate 26's top, transparent equipment shell 25's inside is provided with ball 24. The surface of the chip cover plate 26 is provided with a fastening nut 23, and the chip cover plate 26 and the chip connection device shell 12 are connected through the fastening nut 23. The rubber gasket 27 has excellent flexibility, and can protect the transmission chip 28 during the tightness adjustment process of the fastening nut 23, so as to prevent the chip cover plate 26 from crushing the transmission chip 28. Whether the chip is flat or not can be judged intuitively according to the condition that the ball 24 is in the transparent equipment shell 25, if the ball 24 is in the middle of the transparent equipment shell 25 and is stable and fixed, the chip is flat, if the ball 24 rolls in the transparent equipment shell 25, the chip is uneven, the ball 24 rolls from the high end of the chip to the low end in the transparent equipment shell 25, and the purpose of adjusting the flatness of the chip is achieved through the fastening nut 23 corresponding to the high end.

The side of the embedded controller device shell 1 is provided with a connecting clamping plate 2, the connecting clamping plate 2 is provided with a USB interface 5 which is in plug-in fit with a USB plug 14, the connecting clamping plate 2 and the USB plug 14 are respectively fixed with a first magnet 13 and a second magnet 21, the polarities of the opposite ends of the first magnet 13 and the second magnet 21 are opposite, one end of the USB plug 14, which is far away from the connecting clamping plate 2, is fixedly provided with a second rotating ferrule 18, the outer surface of the second rotating ferrule 18 is uniformly and fixedly connected with a plurality of connecting blocks 17, the outer side of each connecting block 17 is fixedly connected with a first rotating ferrule 16, the outer surface of the first rotating ferrule 16 is movably sleeved with a holding ferrule 15, the first rotating ferrule 16 and the second rotating ferrule 18 are concentrically arranged, a counterweight block 20 is fixedly connected to the bottom of the USB plug 14, the counterweight block 20 is heavier than the weight of the USB plug 14, and two end faces of the holding ferrule 15 are fixedly connected with a limiting block 19 which is matched with the first rotating ferrule 16 and the second rotating ferrule 19, so as to prevent the second rotating ferrule 18 from rotating and falling off. Under the action of the weight block 20, the second rotating ferrule 18 fixedly connected with the USB plug 14 can drive the first rotating ferrule 16 to rotate inside the holding ferrule 15, and the USB plug 14 is always kept in the correct insertion direction no matter how the circumferential position of the holding ferrule 15 is, thereby facilitating the realization of the accurate and rapid insertion operation of the USB plug 14.

The double-phase offside of bearing 6 inner walls of shell has linked firmly telescopic tube 9 respectively, two telescopic tube 9's inside symmetry sliding connection has telescopic link 10, is provided with connecting plate 7 between the opposite side of two telescopic links 10, the both ends of connecting plate 7 have linked firmly connecting rod 11 respectively, connecting rod 11 rotates with telescopic link 10 through the bearing to be connected, the side of connecting plate 7 has linked firmly spacing cover shell 22, the periphery of chip apron 26 links firmly with spacing cover shell 22's inner wall bottom.

The equal fixed mounting in both sides of embedded controller equipment casing 1 has an extension curb plate 30, the catching groove 32 has been seted up to the side of extending curb plate 30, the inside joint of catching groove 32 has a lock joint piece 33, the side fixed clamping of lock joint piece 33 has joint bearing block 29, the top fixed mounting of joint bearing block 29 has dustproof ceiling 31. The clamping bearing block 29 is made of plastic, and can be pulled outwards by force so as to enable the clamping block 33 to move out of the clamping groove 32 of the extension side plate 30, thereby being convenient for cleaning the dustproof ceiling 31.

The side surface of the chip connecting device shell 12 is provided with an exhaust hole, and the surface of the embedded controller device shell 1 is provided with a radiating fin. The exhaust hole can avoid the problem that the heat generated when the transmission chip 28 operates can not be dispersed to influence the performance of the chip due to the fact that the rubber gasket 27 separates the transmission chip 28 for heat dissipation, and the heat dissipation fins can dissipate the heat of the inside of the device, so that the problem that the performance of the device is reduced due to high temperature caused by the fact that the heat of the inside can not be discharged is avoided.

The working principle of the photoelectric image processing device based on big data is as follows: when the transmission chip 28 needs to be replaced by a worker, the connecting clamping plate 2 is detached from the embedded controller device shell 1, the bearing shell 6 slides out of the position above the bearing plate 4 from the inside of the sliding groove 3, the connecting plate 7 is rotated, the connecting plate 7 drives the limiting sleeve 22 to rise, after the chip is replaced, if the ball 24 is in the middle of the transparent device shell 25 and is stable and fixed, the chip is flat, if the ball 24 rolls in the inside of the transparent device shell 25, the chip is uneven, the ball 24 rolls from the high end of the chip to the low end in the transparent device shell 25, and the fastening nut 23 corresponding to the high end is adjusted until the ball 24 is in the middle of the transparent device shell 25 and is stable and fixed. When needing to carry out the USB and connecting, under the effect of counter weight square 20, USB plug 14 remains throughout in the exact direction of inserting, rethread second magnet 21 and first magnet 13 adsorb each other, can assist the exact of USB plug 14 to insert, realizes the accurate quick grafting operation of USB plug 14, through with the buckle piece 33 of the joint bearing block 29 of plastics system with the catching groove 32 joint of extension curb plate 30, make the dustproof ceiling 31 at top carry out dustproof protection to radiating fin.

The invention also provides an implementation method of the photoelectric image processing device based on the big data, which comprises the following steps:

s1, detaching a connecting clamping plate 2 from an embedded controller equipment shell 1, and sliding out of a bearing shell 6 above a bearing plate 4 from the inside of a sliding groove 3;

s2, rotating the connecting plate 7, driving the limiting sleeve 22 to rise by the connecting plate 7, and replacing the chip;

s3, after the chip is replaced, if the ball 24 is in the middle of the transparent equipment shell 25 and is stable and immobile, the chip is flat, the chip is replaced, and the step S5 is carried out; if the ball 24 rolls in the transparent device shell 25, the chip is not flat, and step S4 is performed;

s4, rolling the ball 24 in the transparent equipment shell 25 from the high end of the chip to the low end of the chip, and adjusting the fastening nut 23 corresponding to the high end until the ball 24 is in the middle of the transparent equipment shell 25 and is stable and motionless, and the chip is flat at the moment;

s5, during USB connection, under the action of the counterweight square block 20, the USB plug 14 is always kept in the correct insertion direction, and the second magnet 21 and the first magnet 13 are mutually adsorbed, so that the correct insertion of the USB plug 14 can be assisted, and the accurate and quick insertion operation of the USB plug 14 is realized;

s6, clamping the fastening block 33 of the plastic clamping bearing block 29 with the fastening groove 32 of the extension side plate 30, and performing dustproof protection on the radiating fin through a dustproof ceiling 31 at the top.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The photoelectric image processing device based on the big data is characterized by comprising an embedded controller device shell (1) and a USB plug (14), wherein a sliding groove (3) is formed in the embedded controller device shell (1), a bearing plate (4) is connected to the inside of the sliding groove (3) in a sliding mode, a bearing shell (6) is fixedly connected to the top of the bearing plate (4), a chip connecting device shell (12) is arranged at the bottom end of the inside of the bearing shell (6), a transmission chip (28) is arranged in the chip connecting device shell (12), a rubber gasket (27) is arranged at the top of the transmission chip (28), a chip cover plate (26) is arranged at the top of the rubber gasket (27), a transparent device shell (25) is fixedly connected to the top of the chip cover plate (26), and balls (24) are arranged in the transparent device shell (25); a connecting clamping plate (2) is arranged on the side surface of the embedded controller equipment shell (1), the connecting clamping plate (2) is provided with a USB interface (5) which is in plug-in fit with a USB plug (14), a first magnet (13) and a second magnet (21) are respectively fixed on the connecting clamping plate (2) and the USB plug (14), the polarities of the opposite ends of the first magnet (13) and the second magnet (21) are opposite, a second rotating ferrule (18) is fixedly arranged at one end of the USB plug (14) far away from the connecting clamping plate (2), the outer surface of the second rotating ferrule (18) is evenly and fixedly connected with a plurality of connecting blocks (17), the outer sides of the connecting blocks (17) are fixedly connected with a first rotating ferrule (16) together, a holding ferrule (15) is movably sleeved on the outer surface of the first rotating ferrule (16), the gripping collar (15), the first rotating collar (16) and the second rotating collar (18) are arranged concentrically, a counterweight block (20) is fixedly connected to the bottom of one section of the USB plug (14) between the second magnet (21) and the second rotating ferrule (18), the weight of the counterweight square block (20) is larger than that of the USB plug (14), two end faces of the holding ferrule (15) are respectively fixedly connected with a limiting block (19) matched with the first rotating ferrule (16).

2. The big data based electro-optical image processing apparatus according to claim 1, wherein a surface of the chip cover plate (26) is provided with a fastening nut (23), and the chip cover plate (26) and the chip connection device case (12) are connected by the fastening nut (23).

3. The device for processing the photoelectric image based on the big data according to claim 2, wherein two opposite sides of the inner wall of the bearing shell (6) are respectively fixedly connected with a telescopic tube (9), two telescopic tubes (9) are symmetrically and slidably connected with telescopic rods (10), a connecting plate (7) is arranged between the two opposite sides of the two telescopic tubes (10), two ends of the connecting plate (7) are respectively fixedly connected with a connecting rod (11), the connecting rod (11) is rotatably connected with the telescopic rods (10) through a bearing, a limiting casing (22) is fixedly connected to the side surface of the connecting plate (7), and the periphery of the chip cover plate (26) is fixedly connected with the bottom of the inner wall of the limiting casing (22).

4. The optoelectronic image processing apparatus according to claim 3, wherein an extension side plate (30) is fixedly mounted on each of two sides of the embedded controller device case (1), a fastening groove (32) is formed in a side surface of the extension side plate (30), a fastening block (33) is fastened inside the fastening groove (32), a clamping bearing block (29) is fixedly fastened on a side surface of the fastening block (33), and a dustproof ceiling (31) is fixedly mounted on a top portion of the clamping bearing block (29).

5. The big data based optoelectronic image processing apparatus of claim 4, wherein the side of the chip connection device housing (12) is provided with an exhaust hole, and the surface of the embedded controller device housing (1) is provided with a heat dissipation fin.

6. A method for implementing a big data based electro-optical image processing device according to any of claims 1-5, characterized in that it comprises the following steps:

s1, detaching a connecting clamping plate (2) from an embedded controller equipment shell (1), and sliding out of a bearing shell (6) above a bearing plate (4) from the inside of a sliding groove (3);

s2, rotating the connecting plate (7), wherein the connecting plate (7) drives the limiting sleeve (22) to rise, and replacing the chip;

s3, after the chip is replaced, if the ball (24) is in the middle of the transparent equipment shell (25) and is stable and immobile, the chip is flat, the chip is replaced, and the step S5 is carried out; if the ball (24) rolls in the transparent equipment shell (25), the chip is not flat, and the step S4 is carried out;

s4, rolling the ball (24) in the transparent equipment shell (25) from the high end of the chip to the low end, adjusting the fastening nut (23) corresponding to the high end until the ball (24) is in the middle of the transparent equipment shell (25) and is stable and immobile, and the chip is flat at the moment;

s5, during USB connection, under the action of the counterweight square block (20), the USB plug (14) is always kept in the correct insertion direction, and the second magnet (21) and the first magnet (13) are mutually adsorbed, so that the correct insertion of the USB plug (14) can be assisted, and the accurate and quick insertion operation of the USB plug (14) is realized;

s6, clamping a fastening block (33) of the plastic clamping bearing block (29) with a fastening groove (32) of the extension side plate (30), and performing dustproof protection on the radiating fin through a dustproof ceiling (31) at the top.

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