CN117241113B - High-definition image sensor device convenient to disassemble and assemble and working method - Google Patents

Abstract

The invention belongs to the technical field of image sensors, and particularly discloses a high-definition image sensor device convenient to assemble and disassemble and a working method. According to the invention, the pull tab is rolled by the rotating sleeve in a motor working manner, the pull tab pulls the straight plate to move in a rolling process, the straight plate enables the sleeve plate and the inserting rod to drive the arc plate to be close to the elastic plate, the spring is extruded by the sleeve plate in a process of being close to the bottom frame, the elastic plate is synchronously clamped by the arc plates under the pulling of the pull tabs, when the arc plates are synchronously close to the elastic plate, the elastic plate is enabled to move to the center of the inner side of the bottom frame by the gradually contracted arc plates, so that the high-definition image sensor at the top of the elastic plate corresponds to the center groove of the top frame, the high-definition image sensor is enabled to positively correspond to the camera lens, and shaking of the high-definition image sensor in the shooting process of the camera lens is avoided.

Description

High-definition image sensor device convenient to disassemble and assemble and working method

Technical Field

The invention belongs to the technical field of image sensors, and particularly relates to a high-definition image sensor device convenient to assemble and disassemble and a working method.

Background

The high-definition image sensor utilizes the photoelectric conversion function of a photoelectric device. The high-definition image sensor is a functional device which converts the light image on the light receiving surface into a plurality of small units and converts the small units into usable electric signals compared with the photosensitive elements of 'point' light sources such as a photodiode, a phototriode and the like.

The existing high-definition image sensor fixing device may have fine deviation during installation, and therefore high-definition image sensor installation errors may be caused, and the irradiated image is defective.

Disclosure of Invention

In order to solve the above problems, the present invention provides a high-definition image sensor device and a working method thereof, which are convenient to assemble and disassemble, so as to solve the problems set forth in the background art:

in order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a easy dismounting's high definition image sensor device, includes the top frame to and be in the underframe of top frame bottom, the underframe top surface is provided with the ring strip, top frame bottom opening corresponds the cooperation with underframe top opening, and top frame inside wall bottom corresponds laminating with the ring strip lateral surface, and ring strip and top frame circumference lateral surface spiral run through has a plurality of screws, makes top frame and underframe fixed connection through the mode that a plurality of screws spiral run through, high definition image sensor has been placed to the underframe inside, high definition image sensor bottom is fixed with the elastic plate, and high definition image sensor utilizes the elastic plate to correspond to place in the underframe inboard, the underframe inboard is provided with a plurality of rings of arcs of arranging side by side, concave surface bottom corresponds the laminating with the elastic plate circumference lateral surface in the arc, and a plurality of arcs correspond to inject the elastic plate, and the arc outside both sides all are fixed with the inserted bar that runs through the underframe, the inserted bar outside end is connected with the sleeve plate, sleeve medial surface makes sleeve plate and the outside frame lateral surface utilize spring coupling, the elasticity of spring makes sleeve plate and convex surface drive the outside extrusion circular arc.

Further, the rotating rod spirally penetrating through the bottom frame is rotationally clamped at the center of the outer convex surface of the arc-shaped plate, the outer side end of the rotating rod penetrates through the center of the sleeve plate, the rotating rod is rotated, and the arc-shaped plate moves back and forth inside the bottom frame due to the spiral effect of the rotating rod and the bottom frame.

Further, the arc concave surface both sides all are fixed with the side, the length of side is less than the length of arc, side center department is provided with erects the groove, erect the inside interior pole that is provided with of groove, the concave surface is provided with the horizontal pole that runs through two erects the groove in the arc, interior pole corresponds and runs through the horizontal pole, and the horizontal pole utilizes interior pole to slide from top to bottom at erecting the inslot portion, the horizontal pole top utilizes the elastic strip to be connected with erectting inslot side top, the horizontal pole both ends all are fixed with the plectane, the plectane bottom utilizes the connecting rod to be connected with the clamp plate, the clamp plate bottom surface corresponds with the elastic plate top surface.

Further, a plurality of spouts have been arranged to the top frame top surface annular, the inside slip joint of spout has the slide, slide bottom is fixed with the sill bar, and a plurality of sill bars and the inboard horizontal pole one-to-one of a plurality of arc, utilize the rotating plate to be connected between sill bar and the horizontal pole, the slide inboard is provided with logical groove, utilizes the bent rod to connect between two adjacent slides, and the bent rod both ends are in the logical inslot side of two slides respectively, the bent rod top surface runs through there is the screw rod, and the bent rod utilizes the screw rod to be connected with the top frame top surface.

Further, the center of the top surface of the top frame is provided with a center groove, a plurality of sliding grooves are annularly arranged outside the center groove, and the bottom of the center groove corresponds to the top surface of the high-definition image sensor.

Further, the end part of the bent rod is correspondingly inserted into the through groove of the sliding plate, the sliding plate moves in the sliding groove, the sliding plate utilizes the bent rod to enable the rest sliding plates to synchronously move, and the sliding plates are far away from or close to each other.

Further, the cover board bottom is fixed with straight board, the underframe bottom is provided with the intermediate lever, intermediate lever surface rotation joint has changeing the cover, it is connected to utilize the pulling-on piece between changeing cover circumference lateral surface and the straight board, and changes the external motor output in cover bottom, and motor work utilizes changeing the cover rolling pulling-on piece, and the pulling-on piece utilizes straight board to make the cover board be close to the underframe.

The invention also provides a working method of the high-definition image sensor device convenient to assemble and disassemble, which comprises the following steps:

s1, correspondingly placing an elastic plate on the inner side of a bottom frame, correspondingly placing an opening at the bottom of a top frame at the opening at the top of the bottom frame, then, helically penetrating through the top frame and a ring strip by using a plurality of screws, pulling a sliding plate to move upwards, driving a rotating plate to rotate by the sliding plate, enabling the top end of the rotating plate to rotate on the surface of a bottom rod, enabling the bottom end of the rotating plate to rotate on the surface of a cross rod until the top end of the sliding plate moves out of a sliding groove, and limiting a through groove for clamping two adjacent sliding plates by using a plurality of bent rods;

s2, adjusting the position of the arc-shaped plate according to the appearance of the elastic plate, rotating the rotating rod, pulling the arc-shaped plate to move on the inner side of the bottom frame by the spiral effect of the rotating rod and the bottom frame, enabling the sliding plate to slide in the sliding groove by using the cross rod and the rotating plate when the arc-shaped plate moves until the relative distance between the arc-shaped plate and the elastic plate is completed, fixedly connecting the bent rod with the top frame by using the screw rod, and completing the connection of the sliding plate and the top frame;

s3, starting a motor, wherein the motor works by using a rotating sleeve to roll a pull piece, the pull piece pulls a straight plate to move in the rolling process, the straight plate enables a sleeve plate and an inserting rod to drive an arc plate to be close to an elastic plate, the sleeve plate extrudes a spring in the process of being close to a bottom frame, and a plurality of arc plates synchronously clamp the elastic plate under the pulling of a plurality of pull pieces, so that a high-definition image sensor at the top of the elastic plate corresponds to a central groove of a top frame;

s4, when the arc-shaped plate is close to the elastic plate, the bottom end of the rotating plate is moved by the arc-shaped plate, and the rotating plate extrudes the cross rod due to the limitation of the screw rod and the top frame on the bent rod, so that the elastic strip is pulled in the process that the inner side of the vertical groove moves downwards, and a circular plate at the end of the cross rod extrudes the elastic plate by a pressing plate at the bottom end of the connecting rod in the downwards moving process, so that the high-definition image sensor is installed between the top frame and the bottom frame;

s5, when the high-definition image sensor is replaced, the motor works to enable the rotating sleeve to rotate reversely, the sleeve plate is enabled to be far away from the bottom frame by the aid of the elastic force of the spring, the sleeve plate is pulled out of the rolled pull piece through the straight plate, the arc plate is enabled to be far away from the elastic plate by the aid of the inserting rod, the rotating plate is pulled to rotate reversely by the aid of the elastic force of the elastic strip and the transverse rod, the pressing plate is further enabled to be separated from the elastic plate, the screw is unscrewed, the plurality of sliding plates are separated, the screw is unscrewed, the top frame and the bottom frame are separated, and the high-definition image sensor is conveniently taken out from the bottom frame.

The invention has the technical effects and advantages that:

1. according to the invention, the pull tab is rolled by the rotating sleeve in a motor working manner, the pull tab pulls the straight plate to move in a rolling process, the straight plate enables the sleeve plate and the inserting rod to drive the arc plate to be close to the elastic plate, the spring is extruded by the sleeve plate in a process of being close to the bottom frame, the elastic plate is synchronously clamped by the arc plates under the pulling of the pull tabs, when the arc plates are synchronously close to the elastic plate, the elastic plate is enabled to move to the center of the inner side of the bottom frame by the gradually contracted arc plates, so that the high-definition image sensor at the top of the elastic plate corresponds to the center groove of the top frame, the high-definition image sensor is enabled to positively correspond to the camera lens, and shaking of the high-definition image sensor in the shooting process of the camera lens is avoided.

2. According to the invention, the inner concave surfaces of the arc-shaped plates are correspondingly attached to the outer side surface of the circumference of the elastic plate, the sliding plates are pushed to move, the adjacent sliding plates are enabled to move by the bent rods, at the moment, the adjacent two sliding plates are gradually far away, the moving sliding plates drive the top ends of the rotating plates to move, the rotating plates squeeze the cross rods to push the cross rods to move downwards in the vertical grooves due to limitation of the arc-shaped plates, so that the cross rods pull the elastic strips in the process of moving downwards in the vertical grooves, and the circular plates at the end parts of the cross rods squeeze the elastic plates by the pressing plates at the bottom ends of the connecting rods in the process of moving downwards, so that the installation of the high-definition image sensor between the top frame and the bottom frame is completed, and the elastic plates are prevented from moving upwards and downwards in the inner sides of the bottom frame.

3. According to the invention, the rotating sleeve is reversely rotated through the work of the motor, the sleeve plate is far away from the bottom frame by the elasticity of the spring, the sleeve plate pulls out the rolled pull piece through the straight plate, the arc plate is far away from the elastic plate by the sleeve plate through the inserting rod, the rotating plate is reversely rotated by the elasticity of the elastic strip and the transverse rod, the pressing plate is further separated from the elastic plate, the screw rod is unscrewed, the plurality of sliding plates are separated, the screw is unscrewed, the top frame and the bottom frame are separated, and the high-definition image sensor is conveniently taken out from the inside of the bottom frame.

Drawings

FIG. 1 is a schematic view of a high definition image sensor device according to an embodiment of the present invention;

FIG. 2 is a schematic view of a high definition image sensor positioned inside a base frame according to an embodiment of the present invention;

FIG. 3 is a schematic view of an arc plate inside a bottom frame according to an embodiment of the present invention;

FIG. 4 is a schematic view of a bayonet connection sleeve plate outside a base frame according to an embodiment of the present invention;

FIG. 5 is a schematic view of the overall top frame of an embodiment of the present invention;

FIG. 6 is a schematic view showing a sliding fit of a sliding plate and a sliding slot according to an embodiment of the present invention;

FIG. 7 is a schematic view of a skateboard and rail connection using a swivel plate in accordance with an embodiment of the invention;

FIG. 8 is a schematic view of the bottom structure of a bottom frame according to an embodiment of the present invention;

in the figure: 1. a top frame; 2. a bottom frame; 3. a ring strip; 4. a screw; 5. a high definition image sensor; 6. an elastic plate; 7. an arc-shaped plate; 8. a rod; 9. a sleeve plate; 10. a spring; 11. a rotating rod; 12. a side edge; 13. an inner rod; 14. a cross bar; 15. an elastic strip; 16. a circular plate; 17. a pressing plate; 18. a chute; 19. a slide plate; 20. a bottom bar; 21. a rotating plate; 22. a through groove; 23. bending a rod; 24. a screw; 25. a straight plate; 26. an intermediate lever; 27. a rotating sleeve; 28. and (5) pulling the tab.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the embodiments.

The invention provides a high-definition image sensor device convenient to assemble and disassemble, as shown in fig. 1 to 4, the high-definition image sensor device comprises a top frame 1 and a bottom frame 2 positioned at the bottom of the top frame 1, a ring strip 3 is arranged on the top surface of the bottom frame 2, the bottom opening of the bottom frame 1 is correspondingly matched with the top opening of the bottom frame 2, the bottom of the inner side wall of the top frame 1 is correspondingly attached to the outer side surface of the ring strip 3, a plurality of screws 4 penetrate through the ring strip 3 and the outer side surface of the circumference of the top frame 1 in a spiral manner, the top frame 1 and the bottom frame 2 are fixedly connected in a spiral penetrating manner through the plurality of screws 4, a high-definition image sensor 5 is placed inside the bottom frame 2, an elastic plate 6 is fixed at the bottom of the high-definition image sensor 5, a plurality of circular plates 7 are correspondingly placed inside the bottom frame 2 by utilizing the elastic plate 6, a plurality of circular arrangement circular plates 7 are correspondingly arranged at the inner side surfaces of the bottom of the circular plates 7, the circular outer side surfaces of the circular plates 6 are correspondingly attached to each other, a plurality of inserted bars 8 penetrate through the two sides of the outer side surfaces of the circular plates 7, a sleeve 7 penetrates through the circular plates 8 and the outer side surfaces of the circular plates 9 are connected with the circular plates 10, and the outer side surfaces of the circular plates 9 are connected by utilizing the elastic plates 10, and the outer side surfaces of the inserted bars 10 are connected by the elastic plates 10, and the elastic plates 10 are connected by the elastic plates 10. High definition image sensor 5 utilizes elastic plate 6 to correspondingly place in the underframe 2 inboard, after top frame 1 bottom opening corresponds places in underframe 2 open-ended department, utilize a plurality of screws 4 spiral to run through top frame 1 and annular strip 3, accomplish the integration of top frame 1 and underframe 2 and be connected, before elastic plate 6 places, spring 10's elasticity makes sleeve plate 9 keep away from underframe 2, sleeve plate 9 is keeping away from in-process and utilizes inserted bar 8 to pull arc 7, arc 7 is close to underframe 2 inside wall under spring 10's elasticity drive, until arc 7 circumference lateral surface corresponds with underframe 2 inside wall, the distance between two adjacent arcs 7 is the farthest this moment, conveniently place high definition image sensor 5 in underframe 2 inboard, can place high definition image sensor 5 of adaptation size according to the space of underframe 2 inboard.

In fig. 3 and fig. 4, the rotating rod 11 spirally penetrating through the bottom frame 2 is rotationally clamped at the center of the outer convex surface of the arc-shaped plate 7, the outer side end of the rotating rod 11 penetrates through the center of the sleeve plate 9, and the spiral effect of the rotating rod 11 and the bottom frame 2 enables the arc-shaped plate 7 to move back and forth inside the bottom frame 2 by rotating the rotating rod 11. According to the position of the arc-shaped plate 7 is adjusted according to the appearance of the elastic plate 6, the rotating rod 11 is rotated, the spiral effect of the rotating rod 11 and the bottom frame 2 pulls the arc-shaped plate 7 to move inside the bottom frame 2 until the relative distance between the arc-shaped plate 7 and the elastic plate 6 is completed, and the elastic plates 6 with different sizes are conveniently limited and clamped by the plurality of arc-shaped plates 7 through spiral fit of the rotating rod 11 and the bottom frame 2.

In fig. 2 and fig. 3, both sides of the concave surface in the arc plate 7 are all fixed with side edges 12, the length of the side edges 12 is smaller than the length of the arc plate 7, a vertical groove is formed in the center of the side edges 12, an inner rod 13 is arranged in the vertical groove, the concave surface in the arc plate 7 is provided with a cross rod 14 penetrating through two vertical grooves, the inner rod 13 correspondingly penetrates through the cross rod 14, the cross rod 14 vertically slides in the vertical groove by utilizing the inner rod 13, the top of the cross rod 14 is connected with the top end of the inner side of the vertical groove by utilizing an elastic strip 15, circular plates 16 are fixed at both ends of the cross rod 14, the bottom of each circular plate 16 is connected with a pressing plate 17 by utilizing a connecting rod, and the bottom surface of each pressing plate 17 corresponds to the top surface of the elastic plate 6. When the concave bottom in the arc 7 corresponds the laminating behind the circumference lateral surface of elastic plate 6, need carry out the restriction to elastic plate 6 in vertical direction, promote horizontal pole 14 at the inside downshifting of vertical groove for horizontal pole 14 pulls elastic strip 15 in the inboard downshifting of vertical groove, the plectane 16 of horizontal pole 14 tip utilizes the clamp plate 17 extrusion elastic plate 6 of connecting rod bottom in downshifting the in-process, accomplish the installation of high definition image sensor 5 between top frame 1 and underframe 2, avoid elastic plate 6 to reciprocate at underframe 2 inboard, utilize the double clamping of arc 7 and clamp plate 17, further improve the stability of elastic plate 6 at underframe 2 inboard, thereby make the stable installation of high definition image sensor 5 between top frame 1 and underframe 2.

In fig. 5 to 7, a plurality of sliding grooves 18 are annularly arranged on the top surface of the top frame 1, sliding plates 19 are slidably clamped in the sliding grooves 18, bottom rods 20 are fixed at the bottoms of the sliding plates 19, the bottom rods 20 are in one-to-one correspondence with cross rods 14 on the inner sides of the arc plates 7, the bottom rods 20 are connected with the cross rods 14 through rotating plates 21, through grooves 22 are formed on the inner sides of the sliding plates 19, two adjacent sliding plates 19 are connected through bent rods 23, two ends of each bent rod 23 are respectively located on the inner sides of the through grooves 22 of the two sliding plates 19, screw rods 24 penetrate through the top surfaces of the bent rods 23, and the bent rods 23 are connected with the top surface of the top frame 1 through the screw rods 24. The center of the top surface of the top frame 1 is provided with a center groove, a plurality of sliding grooves 18 are annularly arranged outside the center groove, and the bottom of the center groove corresponds to the top surface of the high-definition image sensor 5. After the top frame 1 and the bottom frame 2 are correspondingly connected by using the screws 4, the sliding plate 19 is pulled to move upwards, the sliding plate 19 drives the rotating plate 21 to rotate, the top end of the rotating plate 21 rotates on the surface of the bottom rod 20, the bottom end of the rotating plate 21 rotates on the surface of the cross rod 14 until the top end of the sliding plate 19 moves out of the sliding groove 18, and a plurality of bent rods 23 are used for limiting the through grooves 22 for clamping two adjacent sliding plates 19. The rotating rod 11 is rotated, the spiral effect of the rotating rod 11 and the bottom frame 2 pulls the arc-shaped plate 7 to move inside the bottom frame 2, the sliding plate 19 slides inside the sliding groove 18 by the aid of the cross rod 14 and the rotating plate 21 when the arc-shaped plate 7 moves until the relative distance between the arc-shaped plate 7 and the elastic plate 6 is finished, the bent rod 23 is fixedly connected with the top frame 1 by means of the screw 24, and connection of the sliding plate 19 and the top frame 1 is finished.

The end of the bending rod 23 is correspondingly inserted into the through groove 22 of the sliding plate 19, the sliding plate 19 moves in the sliding groove 18, the sliding plate 19 utilizes the bending rod 23 to enable the rest sliding plates 19 to synchronously move, and the sliding plates 19 are far away from or close to each other. When the concave surfaces in the arc plates 7 are correspondingly attached to the outer side surfaces of the circumference of the elastic plate 6, the sliding plates 19 are pushed to move, the sliding plates 19 enable the adjacent sliding plates 19 to move by using the bent rods 23, at the moment, the two adjacent sliding plates 19 are gradually far away, the moving sliding plates 19 drive the top ends of the rotating plates 21 to move, due to limitation of the arc plates 7, the rotating plates 21 squeeze the cross rods 14 to push the cross rods 14 to move downwards in the vertical grooves, the cross rods 14 pull the elastic strips 15 in the process of moving downwards in the vertical grooves, the circular plates 16 at the end parts of the cross rods 14 squeeze the elastic plates 6 by using the pressing plates 17 at the bottom ends of the connecting rods in the process of moving downwards, and installation of the high-definition image sensor 5 between the top frame 1 and the bottom frame 2 is completed, so that the elastic plates 6 are prevented from moving upwards and downwards in the inner sides of the bottom frame 2.

In fig. 1, fig. 2 and fig. 8, the straight board 25 is fixed at the bottom of the sleeve board 9, the middle rod 26 is arranged at the bottom of the bottom frame 2, the rotating sleeve 27 is rotatably clamped on the surface of the middle rod 26, the outer circumferential side surface of the rotating sleeve 27 is connected with the straight board 25 by using the pull tab 28, the bottom of the rotating sleeve 27 is externally connected with the output end of the motor, the pull tab 28 is wound by using the rotating sleeve 27 in motor operation, and the sleeve board 9 is close to the bottom frame 2 by using the straight board 25 by using the pull tab 28. The motor work utilizes changeing cover 27 rolling pulling-on piece 28, and the pulling-on piece 28 is in rolling in-process pulling straight board 25 removal, and straight board 25 makes sleeve board 9 and inserted bar 8 drive arc 7 be close to elastic plate 6, and sleeve board 9 is being close to the in-process extrusion spring 10 of underframe 2, and a plurality of arcs 7 synchronous centre gripping elastic plate 6 under the pulling of a plurality of pulling-on pieces 28, and when a plurality of arcs 7 were close to elastic plate 6 in step, a plurality of arcs 7 that shrink gradually made elastic plate 6 remove to underframe 2 inboard center department for the high definition image sensor 5 at elastic plate 6 top corresponds with the centre tank of top frame 1, makes high definition image sensor 5 and camera lens just correspond, avoids high definition image sensor 5 to appear rocking at the camera lens in-process of shooting.

The invention also provides a working method of the high-definition image sensor device which is convenient to assemble and disassemble, and referring to fig. 1 to 8, the working method comprises the following steps:

s1, a high-definition image sensor 5 is correspondingly placed on the inner side of a bottom frame 2 by using an elastic plate 6, after an opening at the bottom of a top frame 1 is correspondingly placed at an opening at the top of the bottom frame 2, a plurality of screws 4 are used for penetrating through the top frame 1 and a ring strip 3 in a spiral manner, a sliding plate 19 is pulled to move upwards, the sliding plate 19 drives a rotating plate 21 to rotate, the top end of the rotating plate 21 rotates on the surface of a bottom rod 20, the bottom end of the rotating plate 21 rotates on the surface of a cross rod 14 until the top end of the sliding plate 19 moves out of a sliding groove 18, and a plurality of bent rods 23 are used for limiting a through groove 22 for clamping two adjacent sliding plates 19;

s2, adjusting the position of the arc-shaped plate 7 according to the appearance of the elastic plate 6, rotating the rotating rod 11, pulling the arc-shaped plate 7 to move inside the bottom frame 2 by the spiral effect of the rotating rod 11 and the bottom frame 2, enabling the sliding plate 19 to slide inside the sliding groove 18 by utilizing the cross rod 14 and the rotating plate 21 when the arc-shaped plate 7 moves until the relative distance between the arc-shaped plate 7 and the elastic plate 6 is completed, fixedly connecting the bent rod 23 and the top frame 1 by utilizing the screw 24, and completing the connection of the sliding plate 19 and the top frame 1;

s3, starting a motor, wherein the motor is used for winding a pull tab 28 by using a rotating sleeve 27, the pull tab 28 pulls a straight plate 25 to move in the winding process, the straight plate 25 enables a sleeve plate 9 and an inserting rod 8 to drive an arc plate 7 to be close to an elastic plate 6, the sleeve plate 9 extrudes a spring 10 in the process of being close to a bottom frame 2, a plurality of arc plates 7 synchronously clamp the elastic plate 6 under the pulling of a plurality of pull tabs 28, and a high-definition image sensor 5 at the top of the elastic plate 6 corresponds to a central groove of a top frame 1;

s4, when the arc-shaped plate 7 is close to the elastic plate 6, the arc-shaped plate 7 utilizes the cross rod 14 to enable the bottom end of the rotating plate 21 to move, the rotating plate 21 extrudes the cross rod 14 due to the limitation of the screw rod 24 and the top frame 1 on the bent rod 23, the cross rod 14 is pulled by the rotating plate 21 in the process of downwards moving the inner side of the vertical groove, the circular plate 16 at the end part of the cross rod 14 utilizes the pressing plate 17 at the bottom end of the connecting rod to extrude the elastic plate 6 in the downwards moving process, and the installation of the high-definition image sensor 5 between the top frame 1 and the bottom frame 2 is completed;

s5, when the high-definition image sensor 5 is replaced, the motor works to enable the rotating sleeve 27 to rotate reversely, the elastic force of the spring 10 enables the sleeve plate 9 to be far away from the bottom frame 2, the sleeve plate 9 pulls out the rolled pull piece 28 through the straight plate 25, the sleeve plate 9 enables the arc plate 7 to be far away from the elastic plate 6 by utilizing the inserting rod 8, the elastic force of the elastic strip 15 and the transverse rod 14 pull the rotating plate 21 to rotate reversely, the pressing plate 17 is further enabled to be separated from the elastic plate 6, the screw 24 is unscrewed, after the sliding plates 19 are separated, the screw 4 is unscrewed, the top frame 1 and the bottom frame 2 are separated, and the high-definition image sensor 5 is conveniently taken out from the inside of the bottom frame 2.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting.

Claims (7)

1. A high definition image sensor device with easy disassembly and assembly, characterized in that: including top frame (1) to and be in underframe (2) of top frame (1) bottom, underframe (2) top surface is provided with ring strip (3), top frame (1) bottom opening corresponds the cooperation with underframe (2) top opening, and top frame (1) inside wall bottom corresponds laminating with ring strip (3) lateral surface, and ring strip (3) and top frame (1) circumference lateral surface spiral run-through has a plurality of screw (4), makes top frame (1) and underframe (2) fixed connection through the mode of a plurality of screw (4) spiral run-through, high definition image sensor (5) have been placed to underframe (2) inside, high definition image sensor (5) bottom is fixed with elastic plate (6), and high definition image sensor (5) utilize elastic plate (6) to correspond to place in underframe (2) inboard, bottom frame (2) inboard is provided with a plurality of circular arc plates (7) of arranging side by side, concave surface and elastic plate (6) circumference face laminating in arc plate (7) and a plurality of arc plates (7) lateral surface correspond, arc plates (8) both sides (8) are fixed with arc plate (8) are fixed with outer side (8), the inner side surface of the sleeve plate (9) is connected with the outer side surface of the bottom frame (2) through a spring (10), and the elasticity of the spring (10) enables the sleeve plate (9) and the inserted link (8) to drive the arc plate (7) to extrude the circumferential outer side surface of the elastic plate (6);

the bottom of the sleeve plate (9) is fixedly provided with a straight plate (25), the bottom of the bottom frame (2) is provided with a middle rod (26), the surface of the middle rod (26) is rotationally clamped with a rotating sleeve (27), the outer side face of the circumference of the rotating sleeve (27) is connected with the straight plate (25) through a pull tab (28), the bottom of the rotating sleeve (27) is externally connected with a motor output end, the motor works by utilizing the rotating sleeve (27) to roll the pull tab (28), the pull tab (28) utilizes the straight plate (25) to enable the sleeve plate (9) to be close to the bottom frame (2), and the sleeve plate (9) extrudes a spring (10) in the process of being close to the bottom frame (2); the motor works to enable the rotating sleeve (27) to rotate reversely, and the elastic force of the spring (10) enables the sleeve plate (9) to be far away from the bottom frame (2).

2. The easy-to-mount and demount high definition image sensor device according to claim 1, wherein: the rotating rod (11) spirally penetrating through the bottom frame (2) is rotationally clamped at the center of the outer convex surface of the arc-shaped plate (7), the outer side end of the rotating rod (11) penetrates through the center of the sleeve plate (9), the rotating rod (11) is rotated, and the spiral effect of the rotating rod (11) and the bottom frame (2) enables the arc-shaped plate (7) to move back and forth inside the bottom frame (2).

3. The easy-to-mount and demount high-definition image sensor device according to claim 2, wherein: the utility model discloses a novel structure of a solar cell panel, including arc (7) concave surface, connecting rod and connecting plate (6), arc (7) concave surface both sides all are fixed with side (12), the length of side (12) is less than the length of arc (7), side (12) center department is provided with erects the groove, erect inslot portion and be provided with interior pole (13), concave surface is provided with horizontal pole (14) that run through two erects the groove in arc (7), interior pole (13) correspond and run through horizontal pole (14), horizontal pole (14) utilize interior pole (13) to slide from top to bottom at erectting inslot portion, horizontal pole (14) top utilizes elastic strip (15) to be connected with erectting inslot top, both ends of horizontal pole (14) all are fixed with plectane (16), plectane (16) bottom utilizes the connecting rod to be connected with clamp plate (17), clamp plate (17) bottom surface corresponds with elastic plate (6) top surface.

4. The easy-to-assemble and disassemble high definition image sensor device according to claim 3, wherein: the top frame (1) top surface annular has arranged a plurality of spouts (18), inside slip joint of spout (18) has slide (19), slide (19) bottom is fixed with sill bar (20), and a plurality of sill bars (20) and the inboard horizontal pole (14) of a plurality of arc (7) one-to-one, utilize revolving plate (21) to be connected between sill bar (20) and horizontal pole (14), slide (19) inboard is provided with logical groove (22), utilizes bent rod (23) to connect between two adjacent slides (19), and bent rod (23) both ends are in logical inslot (22) of two slides (19) respectively, bent rod (23) top surface is run through and is had screw rod (24), and bent rod (23) utilize screw rod (24) to be connected with top frame (1) top surface.

5. The easy-to-assemble and disassemble high definition image sensor device according to claim 4, wherein: the center of the top surface of the top frame (1) is provided with a center groove, a plurality of sliding grooves (18) are annularly arranged outside the center groove, and the bottom of the center groove corresponds to the top surface of the high-definition image sensor (5).

6. The easy-to-assemble and disassemble high definition image sensor device according to claim 5, wherein: the end of the bending rod (23) is correspondingly inserted into a through groove (22) of the sliding plate (19), the sliding plate (19) moves in the sliding groove (18), the sliding plate (19) utilizes the bending rod (23) to enable the rest sliding plates (19) to synchronously move, and the sliding plates (19) are far away from or close to each other.

7. A method of operating a high definition image sensor assembly according to claim 6, wherein: the method comprises the following steps:

s1, a high-definition image sensor (5) is correspondingly placed on the inner side of a bottom frame (2) by using an elastic plate (6), after a bottom opening of a top frame (1) is correspondingly placed at the top opening of the bottom frame (2), a plurality of screws (4) are used for penetrating through the top frame (1) and a ring strip (3) in a spiral mode, a sliding plate (19) is pulled to move upwards, the sliding plate (19) drives a rotating plate (21) to rotate, the top end of the rotating plate (21) rotates on the surface of a bottom rod (20), the bottom end of the rotating plate (21) rotates on the surface of a cross rod (14) until the top end of the sliding plate (19) moves out of a sliding groove (18), and a plurality of bent rods (23) are used for limiting through grooves (22) for buckling two adjacent sliding plates (19);

s2, adjusting the position of an arc-shaped plate (7) according to the appearance of an elastic plate (6), rotating a rotating rod (11), pulling the arc-shaped plate (7) to move inside the bottom frame (2) by the spiral effect of the rotating rod (11) and the bottom frame (2), enabling a sliding plate (19) to slide inside a sliding groove (18) by using a cross rod (14) and a rotating plate (21) when the arc-shaped plate (7) moves until the relative distance between the arc-shaped plate (7) and the elastic plate (6) is completed, fixedly connecting a bent rod (23) with a top frame (1) by using a screw rod (24), and completing the connection of the sliding plate (19) and the top frame (1);

s3, starting a motor, wherein the motor works by using a rotating sleeve (27) to roll a pull tab (28), the pull tab (28) pulls a straight plate (25) to move in the rolling process, the straight plate (25) enables a sleeve plate (9) and an inserting rod (8) to drive an arc plate (7) to be close to an elastic plate (6), the sleeve plate (9) extrudes a spring (10) in the process of being close to a bottom frame (2), a plurality of arc plates (7) synchronously clamp the elastic plate (6) under the pulling of the pull tabs (28), and a high-definition image sensor (5) at the top of the elastic plate (6) corresponds to a central groove of a top frame (1);

s4, when the arc-shaped plate (7) is close to the elastic plate (6), the arc-shaped plate (7) uses the cross rod (14) to enable the bottom end of the rotating plate (21) to move, the rotating plate (21) extrudes the cross rod (14) due to the limitation of the screw rod (24) and the top frame (1) on the bent rod (23), the cross rod (14) is pulled by the rotating plate (21) in the process that the inner side of the vertical groove moves downwards, the circular plate (16) at the end of the cross rod (14) utilizes the pressing plate (17) at the bottom end of the connecting rod to extrude the elastic plate (6) in the downward moving process, and the installation of the high-definition image sensor (5) between the top frame (1) and the bottom frame (2) is completed;

s5, when changing high definition image sensor (5), motor work makes change cover (27) reversal, elasticity of spring (10) makes cover board (9) keep away from underframe (2), and cover board (9) are pulled out through straight board (25) with pull tab (28) of rolling, cover board (9) utilize inserted bar (8) to make arc (7) keep away from elastic plate (6), and elasticity and horizontal pole (14) of elastic strip (15) stimulate rotating plate (21) counter-rotation, and then make clamp plate (17) and elastic plate (6) separation, unscrew screw (24), after separating a plurality of slide (19), unscrew screw (4), separate top frame (1) and underframe (2), conveniently take out high definition image sensor (5) from underframe (2) inside.