CN113142834A

CN113142834A - Integrative collecting box of CD convenient to remove

Info

Publication number: CN113142834A
Application number: CN202110257712.1A
Authority: CN
Inventors: 陈豪虎
Original assignee: Ningbo Huahua Trading Co ltd
Current assignee: Ningbo Huahua Trading Co ltd
Priority date: 2021-03-10
Filing date: 2021-03-10
Publication date: 2021-07-23

Abstract

The invention relates to the technical field of communication equipment, in particular to a conveniently-moved integrated optical disk collecting box which comprises a box body, wherein the upper end surface of the box body is provided with a box body inner cavity along the vertical direction, the left end surface and the right end surface of the box body are provided with handle grooves, the center position of the bottom surface of the box body inner cavity is provided with a rotating shaft groove along the vertical direction, and the upper end surface of the box body is fixedly provided with a top plate; the storage mechanism comprises a storage disc which is rotatably arranged in the inner cavity of the box body; the transmission mechanism comprises a gear which is rotatably arranged on the upper end surface of the box body; the feeding mechanism comprises a rotating disc sleeved at the upper end of the rotating shaft, and the rotating disc is meshed with the gear; the clamping mechanism comprises a positioning shaft groove formed in the lower end face of the rotating disc; the cleaning mechanism comprises a cleaning disc shaft paper cutting mechanism fixedly connected to the upper end face of the top plate; the problem that stacked optical disks are difficult to separate and topple over in the moving process in the prior art is solved.

Description

Integrative collecting box of CD convenient to remove

Technical Field

The invention relates to the technical field of communication equipment, in particular to a conveniently-moved integrated optical disk collecting box.

Background

Optical storage is a mass data storage means using an optical disc as a storage medium, and has the advantages of low energy consumption, mobility, long storage time and the like. The optical storage technology is fully utilized by the optical disc library, the optical disc library takes optical discs as main storage media, and equipment for storing a large amount of data is realized, some existing libraries are provided, a data room can collect and store some data optical discs, the optical discs do not have outer packages for a long time in the storage process, a plurality of optical discs are stacked together and can cause toppling in the moving process, the distance between the stacked optical discs is compact, the optical discs are difficult to separate under the action of static friction force, if the optical discs are separated by the inserting sheets, the phenomenon that the optical discs are scratched due to the fact that the sharpness of the inserting sheets is too high is caused, and the phenomenon that the optical discs are toppled over can also occur in the stacking moving process due to the fact that the number of the optical discs is too large and the storage is inconvenient.

Disclosure of Invention

The invention aims to provide a conveniently-moved integrated optical disk collecting box, which solves the problems that the stacked optical disks are difficult to separate and the phenomenon of toppling occurs in the moving process in the background technology.

The technical scheme of the invention is as follows: a conveniently-moved integrated optical disk collecting box comprises a box body, wherein an inner cavity of the box body is formed in the upper end face of the box body downwards along the vertical direction, handle grooves are formed in the upper portions of the left end face and the right end face of the box body respectively, a rotating shaft groove is formed in the center of the bottom face of the inner cavity of the box body along the vertical direction, a top plate is fixedly arranged on the upper end face of the box body, and the top plate is clamped in the inner cavity of the box body; the storage mechanism comprises a storage disc which is rotatably arranged in the inner cavity of the box body, and the storage disc is sleeved on the outer circumferential surface of the rotating shaft; the transmission mechanism comprises a gear which is rotatably arranged on the upper end surface of the box body; the feeding mechanism comprises a rotating disc sleeved at the upper end of the rotating shaft, and the rotating disc is meshed with the gear; the clamping mechanism comprises a positioning shaft groove formed in the lower end face of the rotating disc; the cleaning mechanism comprises a cleaning disc shaft paper cutting mechanism fixedly connected to the upper end face of the top plate, and the paper cutting mechanism comprises a rotating shaft groove formed in the upper end face of the box body and close to the left end face.

As a preferable scheme in the invention, the storage mechanism further comprises four storage shafts fixedly connected to the upper end surface of the storage disc, the four storage shafts are arranged at equal intervals along the circumferential direction of the storage disc, sliding discs are respectively sleeved on the four storage shafts, four sliding disc through grooves are formed in the upper end surface of each sliding disc downwards along the vertical direction, the four sliding disc through grooves are arranged at equal intervals along the circumferential direction of the sliding disc, two positioning clamping grooves are formed in the inner circumferential surface of each sliding disc along the vertical direction, the two positioning clamping grooves are arranged at equal intervals along the circumferential direction of the sliding disc, two limiting sliding grooves are formed in the circumferential surface of each storage shaft along the axial direction, the two limiting sliding grooves are arranged at equal intervals along the circumferential direction, limiting sliding blocks are respectively arranged in the two limiting sliding grooves in a sliding manner, and one end of each limiting sliding block is fixedly connected with the inner circumferential side wall of the sliding disc, every the up end of storage axle has seted up spacing axle slot along the axial, it is provided with spacing axle to slide in the spacing axle slot, be provided with first spring between the bottom surface in lower terminal surface and the spacing axle slot of spacing axle, two spacing fixture block grooves have been seted up to the circumference lateral wall in spacing axle slot, two spacing fixture block groove is along the equidistant setting of the circumferencial direction of storage axle, every the inside in spacing fixture block groove slides respectively and is provided with spacing fixture block, spacing fixture block spout has been seted up along radial to the last top surface in spacing fixture block groove, be provided with the second spring between the lateral wall in spacing fixture block spout and the spacing fixture block groove, two spacing axle draw-in grooves have been seted up to the periphery of spacing axle, two spacing axle draw-in grooves are along the equidistant setting of the circumferencial direction of spacing axle. When the device is needed to be used, the optical disks are sleeved on the storage shaft, so that the optical disks are arranged on the upper end face of the sliding disk in a stacked manner, after the optical disks are placed on the upper end face of the sliding disk, the through groove of the sliding disk moves downwards along the vertical direction of the storage shaft under the action of the gravity of the optical disks and drives the limiting slide block to slide along the limiting slide groove, the sliding stability of the sliding disk is ensured, the sliding disk is prevented from rotating in the falling process, when the top surface of the positioning clamping groove is contacted with the upper end face of the positioning clamping block, the sliding disk is limited and fixed, meanwhile, the elastic force of the spring is utilized to support the sliding disk, the optical disks are placed on the sliding disk in a stacked manner, the optical disks stacked in a data chamber are convenient to arrange and move, the optical disks are prevented from falling in the moving process, the last optical disk on the upper end face of the sliding disk is, when one sliding disc is full, the rotating shaft can be rotated to drive the storage disc to rotate, and the next sliding disc is stacked to increase the capacity of the device.

As a preferred scheme in the invention, the transmission mechanism further comprises a motor groove formed in the upper end surface of the box body, a motor is limited in the motor groove, the gear is fixedly connected to the output end of the motor, a driven shaft is rotatably arranged on the upper end surface of the box body, and a conveying belt is sleeved between the driven shaft and the output end of the motor. When the clothes are needed, the rotating disc is sleeved on the circumferential surface of the upper end of the rotating shaft, then the motor is started, the driven shaft is driven to rotate through transmission of the conveying belt, and meanwhile, the gear is meshed with the rotating disc to drive the rotating disc to rotate synchronously.

As a preferred scheme in the invention, the feeding mechanism further comprises a feeding through groove formed in the upper end surface of the rotating disc, a feeding chassis is fixedly arranged on the upper end surface of the top plate, a circular chute is vertically and downwardly formed in the upper end surface of the feeding chassis, a circular ring is slidably arranged in the circular chute in the vertical direction, four push rod chutes are radially formed in the feeding chassis, the four push rod chutes are equidistantly arranged in the circumferential direction of the feeding chassis, a feeding shaft groove is vertically and downwardly formed in the upper end surface of the feeding chassis along a central line, the feeding shaft groove is respectively communicated with the four push rod chutes, a feeding shaft is slidably arranged in the feeding shaft groove, push rods are slidably arranged in the four push rod chutes, a third spring is fixedly arranged between the peripheral side surface of each push rod chute and each push rod, and a circular groove is formed in the lower end surface of the top plate in the circumferential direction, the upper end of the storage shaft is arranged in the circular groove in a sliding mode, a top plate feeding through hole is formed in the upper end face of the top plate in the vertical direction, and the circle center of the top plate feeding through hole and the circle center of the feeding chassis are located on the same horizontal line. When the feeding through groove and the feeding chassis are aligned with each other after the rotating disc rotates, the optical disc to be collected is placed in the feeding through groove, falls on the upper end face of the feeding chassis under the action of gravity and is sleeved on the outer circumferential face of the feeding shaft.

As a preferable scheme in the invention, the clamping mechanism further comprises a positioning shaft slidably disposed in the positioning shaft groove, a fourth spring is connected between the top surface of the positioning shaft groove and the upper end surface of the positioning shaft, two positioning shaft slider grooves are vertically formed in the circumferential side wall of the positioning shaft, the two positioning shaft slider grooves are equidistantly arranged in the circumferential direction of the positioning shaft, a positioning shaft slider is slidably disposed in the positioning shaft slider groove, the positioning shaft slider and the circumferential side wall of the positioning shaft are fixedly connected to the lower end surface of the rotating disc, two clamping rod grooves are horizontally formed in the circumferential direction of the positioning shaft, the two clamping rod grooves are equidistantly arranged in the circumferential direction of the positioning shaft, clamping rods are slidably disposed in the two clamping rod grooves, a fifth spring is fixedly disposed between the side end surface of the clamping rod and the side wall of the clamping rod groove, and a clamping rod clamping groove is formed in the circumferential direction of the lower portion of the positioning shaft, and one ends of the two clamping rods, which are far away from the spring in the initial state, are arranged in the clamping rod clamping grooves. When the rotating rotary disc drives the positioning shaft and the feeding shaft to align with each other, the feeding shaft pushes the feeding shaft to move downwards along the vertical direction under the extrusion action of the positioning shaft, meanwhile, the push rod is pushed to move upwards along the radial direction to extrude the third spring, and the extrusion ring moves upwards along the vertical direction of the ring chute, so that the optical disc on the plane of the feeding chassis is jacked up, meanwhile, the positioning shaft pushes the fourth spring towards the upward movement machine under the action of the reaction force of the feeding shaft, and the clamping rods are separated from the clamping rod clamping grooves to extrude the fifth spring, so that the distance between the convex blocks at the lower ends of the two clamping rods is increased, the clamping rods are clamped between the clamping rods under the pushing action of the ring, the optical disc is driven to move along with the continuous movement of the rotating disc, after the positioning shaft is separated from contact with the feeding shaft, the positioning shaft is reset under the action of the fourth spring, and moves towards the clamping rod clamping grooves under the action of the fifth spring, ensuring better clamping effect of the optical disk.

As a preferable scheme in the invention, the cleaning mechanism further comprises a cleaning disc groove which is formed in the upper end face of the top plate by taking the cleaning disc shaft as a circle center, a sponge cleaning disc is rotatably arranged in the cleaning disc groove, the sponge cleaning disc is sleeved on the cleaning disc shaft, and the positioning shaft is meshed with the cleaning disc shaft in the rotating process. When the positioning shaft carrying the movement of the optical disk moves to the upper end of the sponge cleaning disk, the cleaning disk shaft is driven to rotate after the cleaning disk shafts are mutually meshed, so that the sponge cleaning disk is driven to rotate, the storage surface of the optical disk is cleaned, and the phenomenon of drawing the optical disk in the stacking process is avoided; when the positioning shaft rotates to the upper end face of the top plate feeding through hole with the optical disk, the lower end face of the positioning shaft is opposite to the upper end face of the limiting shaft, the positioning shaft pushes the limiting shaft to move downwards along the vertical direction and extrude the first spring, so that the limiting shaft clamping groove is aligned with the side end face of the limiting clamping block, the limiting clamping block pushes the limiting clamping block to be clamped in the limiting shaft clamping groove under the action of the second spring, meanwhile, the positioning shaft pushes the positioning shaft to move downwards under the action of the fourth spring, so that the two clamping rods are separated outwards, the optical coupler falls down from the circumference of the positioning shaft and is sleeved on the circumferential surface of the storage shaft, so that collection and superposition of the optical disk are completed, after the positioning shaft rotates again, the limiting shaft resets under the action of the first spring, and simultaneously, the two limiting clamping blocks are pushed to reset, and limit fixing of the spring sleeved on the storage shaft is completed.

As a preferable scheme in the invention, the paper cutting mechanism further comprises a swing block groove respectively formed on the front and rear end faces of the rotating shaft groove, a paper strip shaft is rotatably arranged inside the rotating shaft groove along the front and rear direction, a connecting shaft groove is formed on the side wall of the swing block groove along the front and rear direction, a connecting shaft is rotatably arranged inside the connecting shaft groove, the connecting shaft is vertically meshed with the driven shaft, one end of the connecting shaft is fixedly connected with the paper strip shaft, a swing block is fixedly arranged on the circumferential side face of the connecting shaft, the swing block is rotatably arranged in the swing block groove, a paper strip discharging groove is formed in the bottom face of the rotating shaft groove along a certain angle direction, the paper strip discharging groove is mutually communicated with an inner cavity of the box body, a cutter groove is formed in the upper end face of the box body along the vertical direction, a cutter is slidably arranged inside the cutter groove, and the lower port of the cutter groove is mutually communicated with the paper strip discharging groove, the utility model discloses a portable cutting machine, including cutter groove, pendulum piece groove, cutter spout, side end face and the bottom surface of cutter spout, the cutter spout has been seted up to the front and back lateral wall in cutter groove, cutter spout and pendulum piece groove intercommunication each other, and it is provided with the cutter slider to slide in the cutter spout, the side end face and the cutter fixed connection of cutter slider, the fixed sixth spring that is provided with between the bottom surface of cutter slider and cutter spout. Before the motor is started, a paper tape is sleeved on the paper tape shaft, so that the end head of the paper tape passes through the paper tape discharging groove and falls on the upper surface of the sliding disc, when the driven shaft rotates, the connecting shaft is driven to synchronously rotate, and the paper tape on the paper strip shaft is driven to synchronously rotate, so that the paper tape slides downwards, simultaneously drives the swinging block to synchronously rotate, the cutter sliding block is pushed by the swinging block to drive the cutter to move downwards along the vertical direction every time the swinging block rotates for one circle, and the sixth spring is extruded, so that the cutter cuts the paper tape at the lower end of the primary paper strip discharge chute, simultaneously, one optical disk slides onto the sliding disk, the front end of the paper tape is positioned on the upper surface of the optical disk along with the rotation of the paper strip shaft again, therefore, by placing paper strips between the optical disks, the intermittence between the stacked optical disks is increased, the phenomenon that the optical disks are scratched due to overhigh sharpness of the inserting sheets due to the fact that the optical disks are difficult to separate under the action of static friction force due to the fact that the distance between the optical disks is tight is avoided.

Advantageous effects

The invention provides a conveniently-moved integrated optical disk collecting box by improvement, compared with the prior art, the invention has the following improvements and advantages:

1. through the arrangement of the storage mechanism, the support of the sliding disk by utilizing the elasticity of the spring is realized, the optical disks are stacked on the sliding disk to facilitate the arrangement and the movement of the optical disks stacked in the data room, the optical disks are prevented from falling in the moving process, the last optical disk on the upper end surface of the sliding disk is conveniently taken out by utilizing the through groove of the sliding disk, the optical disks are prevented from being tightly attached to the upper end surface of the sliding disk,

2. through setting up clearance mechanism, still realize moving the upper end back of sponge clearance dish when the location axle that carries the CD motion, drive the rotation of clearance dish axle after clearance dish axle intermeshing to drive sponge clearance dish and rotate, clear up the storage surface of CD, avoid the CD to appear drawing the dish phenomenon at range upon range of in-process.

3. Through setting up paper cutting mechanism, realized placing the note between the CD, increase the intermittent type between the range upon range of CD, avoid the interval between the CD inseparabler, the CD is difficult to part under the effect of static friction power, utilizes the inserted sheet to part it can lead to the emergence of the phenomenon of fish tail CD because the sharpness of inserted sheet is too high.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a top view of the present invention.

Fig. 3 is a side view of the present invention.

Fig. 4 is a perspective view of fig. 2 taken in section a-a.

Fig. 5 is a partially enlarged view of the portion R in fig. 4.

Fig. 6 is a partially enlarged view of the portion Q in fig. 4.

Fig. 7 is a partially enlarged view of W in fig. 4.

Fig. 8 is a partially enlarged view of a portion E in fig. 4.

Fig. 9 is a cross-sectional view taken at D-D in fig. 3.

Fig. 10 is a cross-sectional view taken at S-S in fig. 2.

Fig. 11 is a partially enlarged view at T in fig. 10.

Fig. 12 is a cross-sectional view at F-F in fig. 3.

Fig. 13 is a partially enlarged view of the Y portion in fig. 12.

In the figure, a box body 10, a handle groove 11, a box body inner cavity 12, a rotating shaft groove 13, a rotating shaft 14, a storage disc 15, a storage shaft 16, a sliding disc 17, a sliding disc through groove 18, a rotating disc 19, a feeding through groove 20, a feeding chassis 21, a circular ring sliding groove 22, a circular ring 23, a push rod sliding groove 24, a push rod 25, a feeding shaft groove 26, a feeding shaft 27, a positioning shaft groove 28, a positioning shaft 29, a positioning shaft slider groove 30, a positioning shaft slider 31, a top plate feeding through hole 32, a limiting shaft groove 33, a limiting shaft 34, a clamping rod groove 35, a clamping rod 36, a clamping rod clamping groove 37, a limiting shaft clamping groove 38, a limiting clamping block groove 39, a limiting clamping block 40, a limiting clamping block sliding groove 41, a circular ring groove 42, a rotating shaft groove 43, a cutter groove 44, a swinging block groove 45, a connecting shaft 46, a swinging block 47, a paper strip shaft 48, a paper strip discharging groove 49, a cutter 50, a driven shaft 51, a conveyor belt 52, a gear 53, a motor groove 54, a motor 55, a motor groove 16, a motor groove 19, a motor groove 20, a motor groove 30, a motor groove 30, a motor groove, a positioning shaft groove 30, Cleaning disc groove 56, sponge cleaning disc 57, cleaning disc shaft 58, top plate 59, connecting shaft groove 60, cutter sliding groove 61, cutter sliding block 62, positioning clamping groove 70, positioning clamping block 71, limiting sliding groove 72 and limiting sliding block 73.

Detailed Description

The present invention will be described in detail with reference to fig. 1 to 13, and the technical solutions in the embodiments of the present invention will be clearly and completely described, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, 3 and 4, the invention relates to a portable integrated optical disc collecting box, which comprises a box body 10, wherein the upper end surface of the box body 10 is provided with a box body inner cavity 12 downwards along the vertical direction, the upper parts of the left and right end surfaces of the box body 10 are respectively provided with a handle groove 11, the central position of the bottom surface of the box body inner cavity 12 is provided with a rotating shaft groove 13 along the vertical direction, the upper end surface of the box body 10 is fixedly provided with a top plate 59, and the top plate 59 is clamped in the box body inner cavity 12; the storage mechanism comprises a storage disc 15 which is rotatably arranged in the inner cavity 12 of the box body, and the storage disc 15 is sleeved on the outer circumferential surface of the rotating shaft 14; the transmission mechanism comprises a gear 53 which is rotatably arranged on the upper end surface of the box body 10; the feeding mechanism comprises a rotating disc 19 sleeved at the upper end of the rotating shaft 14, and the rotating disc 19 is meshed with the gear 53; the clamping mechanism comprises a positioning shaft groove 28 arranged on the lower end surface of the rotating disc 19; the cleaning mechanism comprises a cleaning disc shaft 58 and a paper cutting mechanism which are fixedly connected to the upper end face of the top plate 59, and the paper cutting mechanism comprises a rotating shaft groove 43 which is formed in the upper end face of the box body 10 and is close to the left end face.

As shown in fig. 4 and 5, the storage mechanism further includes four storage shafts 16 fixedly connected to the upper end surface of the storage tray 15, the four storage shafts 16 are arranged at equal intervals along the circumferential direction of the storage tray 15, the four storage shafts 16 are respectively sleeved with sliding trays 17, the upper end surface of each sliding tray 17 is provided with four sliding tray through grooves 18 downward along the vertical direction, the four sliding tray through grooves 18 are arranged at equal intervals along the circumferential direction of the sliding tray 17, the inner circumferential surface of each sliding tray 17 is provided with two positioning slots 70 along the vertical direction, the two positioning slots 70 are arranged at equal intervals along the circumferential direction of the sliding tray 17, the circumferential surface of each storage shaft 16 is provided with two limiting sliding slots 72 along the axial direction, the two limiting sliding slots 72 are arranged at equal intervals along the circumferential direction, the limiting sliders 73 are respectively slidably arranged inside the two limiting sliding slots 72, one end of the limiting sliders 73 is fixedly connected to the inner circumferential side wall of the sliding tray 17, the upper end face of each storage shaft 16 is axially provided with a limiting shaft groove 33, a limiting shaft 34 is arranged in the limiting shaft groove 33 in a sliding mode, a first spring is arranged between the lower end face of the limiting shaft 34 and the bottom face of the limiting shaft groove 33, two limiting clamping block grooves 39 are formed in the circumferential side wall of the limiting shaft groove 33, the two limiting clamping block grooves 39 are arranged at equal intervals in the circumferential direction of the storage shaft 16, a limiting clamping block 40 is arranged in each limiting clamping block groove 39 in a sliding mode, a limiting clamping block sliding groove 41 is formed in the upper top face of each limiting clamping block groove 39 in the radial direction, a second spring is arranged between the side wall of each limiting clamping block sliding groove 41 and each limiting clamping block groove 39, two limiting shaft clamping grooves 38 are formed in the circumferential face of the limiting shaft 34, and the two limiting shaft clamping grooves 38 are arranged at equal intervals in the circumferential direction of the limiting shaft 34.

Further, when the device is needed, the optical disks are sleeved on the storage shaft 16 to be stacked and arranged on the upper end surface of the sliding disk 17, when the optical disks are placed on the upper end surface of the sliding disk 17, the sliding disk through groove 18 moves downwards along the vertical direction of the storage shaft 16 under the action of the gravity of the optical disks and drives the limiting slide block 73 to slide along the limiting slide groove 72, so that the sliding stability of the sliding disk 17 is ensured, the sliding disk 17 is prevented from rotating in the falling process, when the top surface of the positioning clamping groove 70 is contacted with the upper end surface of the positioning clamping block 71, the sliding disk 17 is limited and fixed, meanwhile, the elastic force of the spring is utilized to support the sliding disk 17, the optical disks are stacked on the sliding disk 17 to facilitate the sorting and moving of the optical disks stacked in the data chamber, the optical disks are prevented from falling in the moving process, and the last optical disk on the upper end surface of the sliding disk 17 is conveniently taken out by utilizing the sliding disk through groove 18, the compact disc is prevented from being tightly attached to the upper end face of the sliding disc 17, when one sliding disc 17 is full, the rotating shaft 14 can be rotated to drive the storage disc 15 to rotate, and the next sliding disc 17 is stacked, so that the capacity of the device is increased.

As shown in fig. 4, 8 and 9, the transmission mechanism further includes a motor groove 54 formed in the upper end surface of the box 10, a motor 55 is defined in the motor groove 54, a gear 53 is fixedly connected to an output end of the motor 55, a driven shaft 51 is rotatably arranged on the upper end surface of the box 10, and a conveyor belt 52 is sleeved between the driven shaft 51 and the output end of the motor 55.

Further, when the clothes are needed, the rotating disc 19 is firstly sleeved on the circumferential surface of the upper end of the rotating shaft 14, then the motor 55 is started, the driven shaft 51 is driven to rotate through the transmission of the conveying belt 52, and meanwhile, the gear 53 is meshed with the rotating disc 19 to drive the rotating disc 19 to synchronously rotate.

As shown in fig. 4 and 6, the feeding mechanism further includes a feeding through groove 20 formed on the upper end surface of the rotating disc 19, a feeding chassis 21 is fixedly arranged on the upper end surface of the top plate 59, a circular chute 22 is vertically and downwardly formed on the upper end surface of the feeding chassis 21, a circular ring 23 is slidably arranged in the circular chute 22 along the vertical direction, four push rod chutes 24 are radially formed in the feeding chassis 21, the four push rod chutes 24 are equidistantly arranged along the circumferential direction of the feeding chassis 21, a feeding shaft groove 26 is vertically and downwardly formed on the upper end surface of the feeding chassis 21 along the central line, the feeding shaft groove 26 is respectively communicated with the four push rod chutes 24, a feeding shaft 27 is slidably arranged in the feeding shaft groove 26, push rods 25 are slidably arranged in the four push rod chutes 24, a third spring is fixedly arranged between the peripheral side surface of each push rod chute 24 and each push rod 25, a circular groove 42 is formed on the lower end surface of the top plate 59 along the circumferential direction, the upper end of the storage shaft 16 is slidably arranged in the circular groove 42, the upper end surface of the top plate 59 is provided with a top plate feeding through hole 32 along the vertical direction, and the circle center of the top plate feeding through hole 32 and the circle center of the feeding chassis 21 are on the same horizontal line.

Further, when the feeding through groove 20 and the feeding chassis 21 are aligned with each other after the rotating disc 19 rotates, the optical disc to be collected is placed in the feeding through groove 20, and the optical disc falls on the upper end surface of the feeding chassis 21 under the action of gravity and is sleeved on the outer circumferential surface of the feeding shaft 27.

As shown in fig. 7, 10 and 11, the clamping mechanism further includes a positioning shaft 29 slidably disposed inside the positioning shaft groove 28, a fourth spring is connected between the top surface of the positioning shaft groove 28 and the upper end surface of the positioning shaft 29, two positioning shaft slider grooves 30 are disposed on the circumferential side wall of the positioning shaft 29 along the vertical direction, the two positioning shaft slider grooves 30 are disposed at equal intervals in the circumferential direction of the positioning shaft 29, a positioning shaft slider 31 is slidably disposed inside the positioning shaft slider grooves 30, two clamping rod grooves 35 are disposed on the lower end surface of the positioning shaft slider 31 and the circumferential side wall of the positioning shaft 29, which are fixedly connected to the rotating disc 19, along the horizontal direction, the two clamping rod grooves 35 are disposed at equal intervals in the circumferential direction of the positioning shaft 29, clamping rods 36 are respectively slidably disposed inside the two clamping rod grooves 35, a fifth spring is fixedly disposed between the side end surface of the clamping rod 36 and the side wall of the clamping rod groove 35, a clamping rod groove 37 is disposed on the lower portion of the positioning shaft 29, the ends of the two clamping rods 36 which are far away from the spring in the initial state are arranged in the clamping rod clamping grooves 37.

Further, after the rotating disc 19 drives the positioning shaft 29 and the feeding shaft 27 to align with each other, the feeding shaft 27 pushes the feeding shaft 27 to move downward along the vertical direction under the extrusion action of the positioning shaft 29, meanwhile, the pushing rod 25 is pushed to move upward along the radial direction to extrude the third spring, and the extruding ring 23 moves upward along the vertical direction of the ring chute 22, so as to eject the optical disc on the plane of the feeding chassis 21, meanwhile, the positioning shaft 29 pushes the fourth spring by moving upward under the reaction force of the feeding shaft 27, and the clamping rod 36 is separated from the clamping rod slot 37 to extrude the fifth spring, the distance between the bumps at the lower ends of the two clamping rods 36 is increased, so that the positioning shaft 29 is clamped between the clamping rods 36 under the pushing action of the ring 23, the optical disc is driven to move along with the continuous movement of the rotating disc 19, the positioning shaft 29 is separated from contact with the feeding shaft 27, and the positioning shaft 29 is reset under the action of the fourth spring, the clamping rod 36 moves into the clamping rod slot 37 under the action of the fifth spring, so that the better clamping effect of the optical disk is ensured.

As shown in fig. 9, the cleaning mechanism further includes a cleaning disk groove 56 formed in the upper end surface of the top plate 59 and centered on the cleaning disk shaft 58, a sponge cleaning disk 57 is rotatably disposed inside the cleaning disk groove 56, the sponge cleaning disk 57 is sleeved on the cleaning disk shaft 58, and the positioning shaft 29 is engaged with the cleaning disk shaft 58 in the rotating process.

Further, after the positioning shaft 29 carrying the movement of the optical disc moves to the upper end of the sponge cleaning disc 57, the cleaning disc shaft 58 is driven to rotate after the cleaning disc shafts 58 are mutually meshed, so that the sponge cleaning disc 57 is driven to rotate, the storage surface of the optical disc is cleaned, and the disc drawing phenomenon of the optical disc in the stacking process is avoided; after the positioning shaft 29 carries the optical disc and rotates to the upper end surface of the top plate feeding through hole 32, the lower end surface of the positioning shaft 29 is opposite to the upper end surface of the limiting shaft 34, the positioning shaft 29 pushes the limiting shaft 34 to move downwards along the vertical direction and extrude the first spring, so that the limiting shaft clamping groove 38 is aligned with the side end surface of the limiting clamping block 40, the limiting clamping block 40 pushes the limiting clamping block 40 to be clamped in the limiting shaft clamping groove 38 under the action of the second spring, meanwhile, the positioning shaft 29 pushes the positioning shaft 29 to move downwards under the action of a fourth spring, so that the two clamping rods 36 are separated outwards, the optical coupler falls down from the circumference of the positioning shaft 29 and is sleeved on the circumference of the storage shaft 16, thereby completing the collection and superposition of the optical disks, when the positioning shaft 29 rotates again, the limit shaft 34 is reset under the action of the first spring, and simultaneously, the two limiting clamping blocks 40 are extruded to reset to complete the limiting fixation of the spring sleeved on the storage shaft 16.

As shown in fig. 9, 12 and 13, the paper cutting mechanism further includes a swing block groove 45 respectively formed on the front and rear end surfaces of the rotation shaft groove 43, a paper strip shaft 48 is rotatably provided inside the rotation shaft groove 43 along the front and rear direction, a connection shaft groove 60 is formed on the side wall of the swing block groove 45 along the front and rear direction, a connection shaft 46 is rotatably provided inside the connection shaft groove 60, the connection shaft 46 is vertically engaged with a driven shaft 51, one end of the connection shaft 46 is fixedly connected with the paper strip shaft 48, a swing block 47 is fixedly provided on the circumferential side surface of the connection shaft 46, the swing block 47 is rotatably provided in the swing block groove 45, a paper strip discharge groove 49 is formed on the bottom surface of the rotation shaft groove 43 along a certain angle direction, the paper strip discharge groove 49 is communicated with the box inner cavity 12, a cutter groove 44 is formed on the upper end surface of the box 10 along the vertical direction, a cutter 50 is slidably provided inside the cutter groove 44, the lower end opening of the cutter groove 44 is communicated with the paper strip discharge groove 49, the front side wall and the rear side wall of the cutter groove 44 are provided with cutter sliding grooves 61, the cutter sliding grooves 61 are communicated with the swing block groove 45, cutter sliding blocks 62 are arranged in the cutter sliding grooves 61 in a sliding mode, the side end faces of the cutter sliding blocks 62 are fixedly connected with the cutter 50, and sixth springs are fixedly arranged between the cutter sliding blocks 62 and the bottom face of the cutter sliding grooves 61.

Further, before the motor 55 is started, a paper tape is sleeved on the paper tape shaft 48, so that the end of the paper tape passes through the paper tape discharging groove 49 and falls on the upper surface of the sliding disc 17, when the driven shaft 51 rotates, the connecting shaft 46 is driven to synchronously rotate, the paper tape on the paper tape shaft 48 is driven to synchronously rotate, the paper tape slides downwards, the swinging block 47 is driven to synchronously rotate, the swinging block 47 pushes the cutter slider 62 every time of rotating for one circle, the cutter 50 is driven to downwards move along the vertical direction, and the sixth spring is extruded, so that the cutter 50 cuts the paper tape at the lower end of the paper tape discharging groove 49 once, meanwhile, one optical disc slides on the sliding disc 17, along with the rotation of the paper tape shaft 48 again, the front end of the paper tape is positioned on the upper surface of the optical disc, so that the intermittence among the stacked optical discs is increased by placing the paper tapes between the optical discs, the space among the optical discs is prevented from being tight, and the optical discs are difficult to separate under the action of static friction force, the phenomenon that the optical disk is scratched due to the high sharpness of the inserting sheet can occur when the inserting sheet is used for separating the optical disks.

Claims

1. The utility model provides an integrative collecting box of CD convenient to remove, includes box (10), its characterized in that: an inner box cavity (12) is formed in the upper end face of the box body (10) in the downward direction along the vertical direction, handle grooves (11) are formed in the upper portions of the left end face and the right end face of the box body (10) respectively, a rotating shaft groove (13) is formed in the center of the bottom face of the inner box cavity (12) along the vertical direction, a top plate (59) is fixedly arranged on the upper end face of the box body (10), and the top plate (59) is clamped in the inner box cavity (12);

the storage mechanism comprises a storage disc (15) which is rotatably arranged in the inner cavity (12) of the box body, and the storage disc (15) is sleeved on the outer circumferential surface of the rotating shaft (14);

the transmission mechanism comprises a gear (53) which is rotatably arranged on the upper end surface of the box body (10);

the feeding mechanism comprises a rotating disc (19) sleeved at the upper end of the rotating shaft (14), and the rotating disc (19) is meshed with the gear (53);

the clamping mechanism comprises a positioning shaft groove (28) formed in the lower end face of the rotating disc (19);

the cleaning mechanism comprises a cleaning disc shaft (58) fixedly connected with the upper end surface of the top plate (59)

The paper cutting mechanism comprises a rotating shaft groove (43) which is formed in the upper end surface of the box body (10) and close to the left end surface.

2. A portable integrated optical disc collecting case according to claim 1, wherein: the storage mechanism further comprises four storage shafts (16) fixedly connected to the upper end face of the storage disc (15), the four storage shafts (16) are arranged at equal intervals along the circumferential direction of the storage disc (15), sliding discs (17) are respectively sleeved on the four storage shafts (16), four sliding disc through grooves (18) are formed in the upper end face of each sliding disc (17) downwards along the vertical direction, the four sliding disc through grooves (18) are arranged at equal intervals along the circumferential direction of the sliding disc (17), two positioning clamping grooves (70) are formed in the inner circumferential face of each sliding disc (17) along the vertical direction, the two positioning clamping grooves (70) are arranged at equal intervals along the circumferential direction of the sliding disc (17), two limiting sliding chutes (72) are formed in the circumferential face of each storage shaft (16) along the axial direction, and the two limiting sliding chutes (72) are arranged at equal intervals along the circumferential direction, the inner parts of the two limiting sliding grooves (72) are respectively provided with a limiting sliding block (73) in a sliding manner, one end of each limiting sliding block (73) is fixedly connected with the inner circumferential side wall of the sliding disc (17), the upper end surface of each storage shaft (16) is provided with a limiting shaft groove (33) along the axial direction, a limiting shaft (34) is arranged in each limiting shaft groove (33) in a sliding manner, a first spring is arranged between the lower end surface of each limiting shaft (34) and the bottom surface of each limiting shaft groove (33), the circumferential side wall of each limiting shaft groove (33) is provided with two limiting clamping block grooves (39), the two limiting clamping block grooves (39) are arranged at equal intervals along the circumferential direction of the storage shaft (16), the inner part of each limiting clamping block groove (39) is respectively provided with a limiting clamping block (40) in a sliding manner, and the upper top surface of each limiting clamping block groove (39) is provided with a limiting clamping block sliding groove (41) along the radial direction, a second spring is arranged between the side wall of the limiting clamping block sliding groove (41) and the limiting clamping block groove (39), two limiting shaft clamping grooves (38) are formed in the circumferential surface of the limiting shaft (34), and the two limiting shaft clamping grooves (38) are arranged at equal intervals in the circumferential direction of the limiting shaft (34).

3. A portable integrated optical disc collecting case according to claim 1, wherein: drive mechanism is still including offering motor groove (54) at box (10) up end, the inside of motor groove (54) is injectd and is provided with motor (55), gear (53) fixed connection is at the output of motor (55), the up end of box (10) rotates and is provided with driven shaft (51), the cover is equipped with conveyer belt (52) between the output of driven shaft (51) and motor (55).

4. A portable integrated optical disc collecting case according to claim 2, wherein: the feeding mechanism further comprises a feeding through groove (20) formed in the upper end face of the rotating disc (19), the upper end face of the top plate (59) is fixedly provided with a feeding chassis (21), the upper end face of the feeding chassis (21) is vertically and downwards provided with a circular sliding groove (22), a circular ring (23) is arranged in the circular sliding groove (22) in a sliding mode along the vertical direction, four push rod sliding grooves (24) are radially formed in the feeding chassis (21), the four push rod sliding grooves (24) are arranged in the circumferential direction of the feeding chassis (21) at equal intervals, a feeding shaft groove (26) is vertically and downwards formed in the upper end face of the feeding chassis (21) along the central line, the feeding shaft groove (26) is respectively communicated with the four push rod sliding grooves (24), a feeding shaft (27) is arranged in the feeding shaft groove (26) in a sliding mode, and a push rod (25) is arranged in the four push rod sliding grooves (24) in a sliding mode, every be fixed between the periphery side of push rod spout (24) and every push rod (25) be provided with the third spring, circular ring groove (42) have been seted up along the circumferencial direction to the lower terminal surface of roof (59), the upper end of storage axle (16) slides and sets up in circular ring groove (42), roof feed-through hole (32) have been seted up along vertical direction to the upper end of roof (59), the centre of a circle of roof feed-through hole (32) is in on the same water flat line with the centre of a circle of feeding chassis (21).

5. A portable integrated optical disc collecting case according to claim 1, wherein: the clamping mechanism further comprises a positioning shaft (29) which is arranged in the positioning shaft groove (28) in a sliding mode, a fourth spring is connected between the top surface of the positioning shaft groove (28) and the upper end surface of the positioning shaft (29), two positioning shaft slider grooves (30) are formed in the circumferential side wall of the positioning shaft (29) along the vertical direction, the two positioning shaft slider grooves (30) are arranged at equal intervals in the circumferential direction of the positioning shaft (29), a positioning shaft slider (31) is arranged in the positioning shaft slider grooves (30) in a sliding mode, the positioning shaft slider (31) and the circumferential side wall of the positioning shaft (29) are fixedly connected with the lower end surface of the rotating disc (19) along the horizontal direction, two clamping rod grooves (35) are arranged at equal intervals in the circumferential direction of the positioning shaft (29), and clamping rods (36) are respectively arranged in the two clamping rod grooves (35) in a sliding mode, fixed being provided with the fifth spring between the lateral end face of supporting rod (36) and the lateral wall in supporting rod groove (35), supporting rod draw-in groove (37), two have been seted up to the lower part circumferencial direction of location axle (29) the one end of keeping away from the spring under supporting rod (36) initial state is seted up in supporting rod draw-in groove (37) and is seted up supporting rod draw-in groove (37), two keep away from the one end of spring under supporting rod (36) initial state and set up in supporting rod draw-in groove (37).

6. A portable integrated optical disc collecting case according to claim 5, wherein: the cleaning mechanism further comprises a cleaning disc groove (56) which is formed in the upper end face of the top plate (59) and takes the cleaning disc shaft (58) as a circle center, a sponge cleaning disc (57) is arranged inside the cleaning disc groove (56) in a rotating mode, the sponge cleaning disc (57) is sleeved on the cleaning disc shaft (58), and the positioning shaft (29) is meshed with the cleaning disc shaft (58) in the rotating process.

7. A portable integrated optical disc collecting case according to claim 3, wherein: the paper cutting mechanism further comprises swing block grooves (45) respectively formed in front and rear side end faces of the rotating shaft groove (43), a paper strip shaft (48) is rotatably arranged in the rotating shaft groove (43) along the front and rear direction, connecting shaft grooves (60) are formed in side walls of the swing block grooves (45) along the front and rear direction, a connecting shaft (46) is rotatably arranged in the connecting shaft grooves (60), the connecting shaft (46) is vertically meshed with a driven shaft (51), one end of the connecting shaft (46) is fixedly connected with the paper strip shaft (48), swing blocks (47) are fixedly arranged on circumferential side faces of the connecting shaft (46), the swing blocks (47) are rotatably arranged in the swing block grooves (45), a paper strip discharging groove (49) is formed in the bottom face of the rotating shaft groove (43) along a certain angle direction, the paper strip discharging groove (49) is communicated with a box body inner cavity (12), a cutter groove (44) is formed in the upper end face of the box body (10) along the vertical direction, the paper slip cutting machine is characterized in that a cutter (50) is arranged in the cutter groove (44) in a sliding mode, the lower end opening of the cutter groove (44) is communicated with a paper strip discharging groove (49), cutter sliding grooves (61) are formed in the front side wall and the rear side wall of the cutter groove (44), the cutter sliding grooves (61) are communicated with a swing block groove (45), a cutter sliding block (62) is arranged in the cutter sliding grooves (61) in a sliding mode, the side end face of the cutter sliding block (62) is fixedly connected with the cutter (50), and a sixth spring is fixedly arranged between the cutter sliding block (62) and the bottom face of the cutter sliding groove (61).