CN216353345U - CD ferrying device with destroy function - Google Patents

Abstract

The present invention provides an optical disk ferrying device with a destroying function, which comprises: the device comprises a shell, a feeding module, a network A optical drive, a network B optical drive, an optical drive mainboard assembly and a ferry assembly; a, burning the optical disk by the optical disk drive; b, the optical disk drive reads the optical disk; the ferry assembly comprises a moving part; the moving piece moves to a fixed loading position, and the optical disk is grabbed from the loading module or is stored back to the loading module at the loading position; the feeding module comprises a feeding container and a container driving device, wherein the feeding container is divided into an optical disk destroying area and an optical disk storage area; the container driving device drives the feeding container to move so as to switch the feeding container corresponding to the feeding position into an optical disk destroying area or an optical disk storage area. The feeding container is provided with an optical disk destroying area, and an optical disk storing confidential data is immediately stored in the optical disk destroying area after ferrying is completed so as to enter an optical disk destroying step, so that the confidentiality of the optical disk ferrying device is improved.

Description

CD ferrying device with destroy function

Technical Field

The utility model relates to the field of data security equipment, in particular to an optical disk ferrying device with a destroying function.

Background

With the development of information technology, the application of the internet has penetrated into various fields of social life, information security and network security have become a subject of the development of human society, personal privacy, company intellectual property and trade secrets, and protection of government and national secrets are more and more emphasized, and in order to protect information security and network security, a dedicated network for physical isolation is usually established to prevent external intrusion; however, in operation, a large amount of information and data needs to be exported from a physically isolated intranet to an extranet, and how to solve the security problem in the process of exporting the internal information data to the extranet becomes an important issue of information and network security.

The data Pump technology is a Pump technology proposed by myogh. Although the data pump technology realizes the unidirectional transmission of data from inside to outside, the protocol transmission is bidirectional, so that if the protocol is hidden by Trojan horse, the reverse transmission is difficult to be eliminated by using the protocol.

The principle of the optical fiber unidirectional transmission technology that optical signals are taken as the unidirectional transmission technology is mainly characterized in that the safe and reliable unidirectional transmission is realized by utilizing the characteristic that the optical signals are transmitted and received in one optical fiber in an irreversible manner. The main method uses a unidirectional optical fiber card to realize optical transmission and reception to achieve the purpose of unidirectional transmission, and a transmitting end and a receiving end are respectively connected with a PC (personal computer) and a USB (universal serial bus) interface to realize point-to-point information unidirectional introduction. The technology can solve the information exchange between the outer network magnetic medium and the inner network magnetic medium, effectively prevents ferry trojans, but still needs to use the inner network magnetic medium, and the risk of secret leakage is still lost in the management and control of the inner network magnetic medium.

The physical isolation transmission technology is a data transmission technology with higher safety, and is characterized in that communication data transmission between data transmission networks can be avoided through physical isolation, and further attack and damage of Trojan horse or virus programs on the data storage network through a communication data transmission channel are avoided. Specifically, the physical isolation transmission technology is used for data transmission by means of an intermediate memory between data storage networks, and the transmission mode can ensure that data information between the data networks is transmitted in a unidirectional manner, and the transmission mode is more effective in isolation of trojans or computer viruses in the existing data transmission technology. However, the process of performing physical isolation is complicated due to the transmission method, and the physical isolation depends on the mutual matching of the components, so the physical isolation often has the problems of large occupied space caused by difficult matching of the components, or wasted space between the components, and also causes the capacity of the intermediate storage (optical disc) to be limited and to be frequently replaced. Meanwhile, the existing physical isolation technology or equipment cannot destroy the read intermediate memory in time, and the confidentiality is weak.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to overcoming at least one of the disadvantages of the related art as set forth above and to providing a disk ferry device with a destruction function.

The technical scheme adopted by the utility model is as follows:

an optical disk ferrying device with a destruction function, comprising: the device comprises a shell, a feeding module, a network A optical drive, a network B optical drive, an optical drive mainboard assembly and a ferry assembly; the loading module is used for storing the optical disk; the A-network optical drive acquires an optical disk by popping up a first optical drive tray and records the optical disk; the B-network optical drive acquires the optical disk by popping up a second optical drive tray and reads the optical disk; the ferry component is used for moving the optical disk among the feeding module, the network A optical drive and the network B optical drive; the ferry assembly comprises a moving part; the moving piece moves to a fixed loading position, and the optical disk is grabbed from the loading module or is stored back to the loading module at the loading position; the feeding module comprises a feeding container and a container driving device; the feeding container is divided into an optical disc destroying area and an optical disc storage area; the container driving device drives the feeding container to move so as to switch the feeding container corresponding to the feeding position into an optical disk destroying area or an optical disk storage area.

The optical disk destroying area is used for accommodating optical disks which need to be destroyed for security reasons after burning so as to limit the condition that the optical disks are taken out manually to steal data; the optical disc storage area is used for storing blank optical discs or recorded optical discs which do not need to be destroyed.

Further, the optical disc destroying area is a first through hole on the feeding container; a destroying part is arranged at the bottom of the shell corresponding to the feeding position; when the feeding container corresponding to the feeding position is switched to the first through hole, the optical disc to be destroyed can pass through the through hole to reach the destruction part.

The destruction part at the bottom of the shell is used for directly destroying the optical disc or enabling the optical disc to reach a special optical disc destruction device, the swing assembly directly stores the optical disc to be destroyed into an optical disc destruction area which is a through hole after the B-network optical drive finishes reading, and the optical disc passes through the first through hole and reaches the destruction part.

Further, the destroying part is a second through hole at the bottom of the shell and is used for connecting the optical disc destroying device; when the feeding container corresponding to the feeding position is switched to the first through hole, the first through hole is aligned to the second through hole to form an avoiding channel, so that the optical disc to be destroyed passes through the avoiding channel to reach the optical disc destroying device.

When the optical disc is required to be destroyed, the first through hole is driven to reach the position corresponding to the feeding position, and the first through hole and the second through hole are respectively used as an inlet and an outlet of the optical disc entering the avoiding channel, so that the optical disc reaches an optical disc destroying device such as an optical disc crusher and the like connected with the outside; when the optical disk is normally taken and placed, the optical disk storage position is located at the position corresponding to the material loading position and covers the second through hole.

Further, the container driving device drives the feeding container to rotate so as to switch the feeding container corresponding to the feeding position to be an optical disc destruction area or an optical disc storage area.

Further, the feeding container comprises a disc and a pudding barrel, and the pudding barrel is arranged on the upper surface of the disc; the optical disk destroying area is arranged on the upper surface part of the disk, which is not provided with the pudding barrel, and the optical disk storage area is arranged in the pudding barrel; the optical disc destroying area and the pudding barrel are uniformly distributed along the circumference of the disc; the container driving device drives the circular disc to rotate around the circular mandrel of the circular disc.

Further, the ferry assembly comprises a vertical guide rail and a ferry driving device; the moving part is driven by the ferry driving device to move along the vertical guide rail; the vertical guide rail is arranged on an axis, and the optical disc placing position after the first optical disc drive tray is popped out, the optical disc placing position and the material loading position after the second optical disc drive tray is popped out are distributed on the axis.

Further, the moving part comprises a vacuum chuck driving module and a vacuum chuck module, and the vacuum chuck driving module is connected with the vacuum chuck module; the vacuum chuck driving module comprises a mounting seat and a negative pressure vacuum system; the vertical guide rail and the negative pressure vacuum system are respectively connected with the mounting base; the vacuum sucker module comprises a fixing piece and a plurality of guide posts which are connected with the fixing piece and are uniformly arranged, one ends of the guide posts are connected with the negative pressure vacuum system, the other ends of the guide posts are sequentially provided with a spring and a sucker, one end of the spring is connected with the fixing piece, and the other end of the spring is connected with the sucker; the negative pressure vacuum system is connected with the fixing piece through a gasket, and the fixing piece and the gasket are respectively connected with the mounting seat.

Further, the negative pressure vacuum system comprises a vacuum pump, an air seat and a control processing system, wherein the air seat is provided with an air suction port and a plurality of air suction ports, the air suction port is connected with the vacuum pump through an air pipe, the air suction ports are connected with the guide columns through vacuum pipelines, and the control processing system is connected with the vacuum pump; the control processing system comprises a pressure sensor, a bearing sensor, an electromagnetic valve and a control processor, wherein the pressure sensor is connected with the control processor and a vacuum pipeline, and the weighing sensor, the electromagnetic valve and the vacuum pump are respectively connected with the control processor.

Further, still include the control module, the control module includes: the system comprises a touch screen, a PLC (programmable logic controller), an A-network CD-ROM drive tray pop-up state detection sensor, a B-network CD-ROM drive tray pop-up state detection sensor, a horizontal sensor and a vertical sensor; the touch screen is used for issuing a control instruction; the A-network CD driver tray popup state detection sensor detects whether a first CD driver tray corresponding to the A-network CD driver is in a popup state; the B-network optical drive tray popup state detection sensor detects whether a second optical drive tray corresponding to the B-network optical drive is in a popup state; the horizontal sensor and the vertical sensor jointly detect whether the feeding module is at a preset position; the PLC controller controls the ferry component, the A-net CD driver, the B-net CD driver and the feeding module through feedback information of the A-net CD driver tray ejection state detection sensor, the B-net CD driver tray ejection state detection sensor, the vertical sensor, the horizontal sensor and the moving part.

Further, the number of the ferry assemblies is at least two; the number of the network A optical drives and the number of the network B optical drives are the same as that of the ferry components, and the network A optical drives, the network B optical drives and the ferry components are arranged in a one-to-one manner; the material loading positions of different ferry assemblies are different; the CD-ROM main board component is connected with all the A-network CD-ROM drives and the B-network CD-ROM drives.

Compared with the prior art, the utility model has the beneficial effects that:

(1) the feeding container is provided with an optical disk destroying area, and an optical disk storing confidential data is immediately stored in the optical disk destroying area after ferrying is completed so as to enter an optical disk destroying step, so that the confidentiality of the optical disk ferrying device is improved.

(2) The first through hole and/or the second through hole simply realize the storage of the optical disk to be destroyed, simplify the internal structure of the optical disk ferrying device, and save the internal space of the optical disk ferrying device.

(3) The arrangement of the standby ferry component ensures that the optical disk ferry device can still normally operate when a single ferry component fails, and simultaneously starts a plurality of ferry components when needed, so that the upper limit of ferry efficiency is improved, the placement number of optical disks is increased by matching with a movable feeding container, the feeding processes of the plurality of ferry components are coordinated, and data confusion is avoided.

Drawings

Fig. 1 is a plan view of an optical disk ferry device according to an embodiment of the present invention.

Fig. 2 is a front view of an optical disk ferry device according to an embodiment of the present invention.

Fig. 3 is an enlarged perspective view of the mover of the embodiment of the present invention.

Fig. 4 is a perspective view of the whole device according to the embodiment of the present invention.

Description of reference numerals: a ferry assembly 10; a moving member 11; a mounting seat 111; a fixing member 112; a gasket 113; a guide post 114; a spring 115; a suction cup 116; an air extraction opening 117; a suction port 118; an air seat 119; a vertical guide rail 12; a ferry drive 13; a network A optical drive 20; a network B optical drive 30; a CD-ROM drive motherboard assembly 40; a feeding module 50; a disc 51; an optical disc storage area 52; a pudding tub 52; the container driving device 53; a control module 60; an optical disc destruction area 70; a first through-hole 70; a destruction section 80; a second through hole 80.

Detailed Description

The drawings are only for purposes of illustration and are not to be construed as limiting the utility model. For a better understanding of the following embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

Example 1

As shown in fig. 1 to 4, the present embodiment provides an optical disc ferry device with a destruction function, including: the optical disk drive comprises a shell, an optical drive mainboard component 40, an A-network optical drive 20, a B-network optical drive 30, an optical drive mainboard component 40 and a ferry component 10; the optical disc drive main board assembly 40 is used for storing optical discs; the A-network optical drive 20 ejects a first optical drive tray to obtain an optical disk and records the optical disk; the network B optical drive 30 acquires the optical disk by popping up a second optical drive tray and reads the optical disk; the ferry assembly 10 is used for moving the optical disc among the optical disc drive main board assembly 40, the network A optical disc drive 20 and the network B optical disc drive 30; the ferry assembly 10 includes a moving member 11; the moving member 11 moves to a fixed loading position, and the optical disc is grabbed from the optical drive main board assembly 40 or stored back to the optical drive main board assembly 40 at the loading position; the optical drive mainboard assembly 40 comprises a feeding container and a container driving device 53; the feeding container is divided into a disc destruction area 70 and a disc storage area 52; the container driving device 53 drives the loading container to move, so as to switch the loading container corresponding to the loading position to be the optical disc destruction area 70 or the optical disc storage area 52.

The optical disc destruction area 70 is used for accommodating optical discs which need to be destroyed for security reasons after being burned, so as to limit the situation that the optical discs are taken out manually to steal data; the disc storage area 52 is used for storing blank discs or recorded discs that do not need to be destroyed.

Preferably, the optical disc destruction area 70 is a first through hole 70 on the loading container; a destroying part 80 is arranged at the bottom of the shell corresponding to the feeding position; when the loading container corresponding to the loading position is switched to the first through hole 70, the optical disc to be destroyed passes through the through hole to reach the destruction part 80.

The destruction part 80 at the bottom of the housing is used for directly destroying the optical disc or enabling the optical disc to reach a special optical disc destruction device, after the B-network optical drive 30 finishes reading, the ferry assembly 10 directly stores the optical disc to be destroyed into the optical disc destruction area 70 which is a through hole, and the optical disc passes through the first through hole 70 and reaches the destruction part 80.

Specifically, the destruction part 80 is a second through hole 80 at the bottom of the outer shell and is used for connecting the optical disc destruction device; when the feeding container corresponding to the feeding position is switched to the first through hole 70, the first through hole 70 is aligned with the second through hole 80 to form an avoiding channel, so that the optical disc to be destroyed passes through the avoiding channel to reach the optical disc destroying device.

When the optical disc needs to be destroyed, the first through hole 70 is driven to reach the position corresponding to the feeding position, and the first through hole 70 and the second through hole 80 are respectively used as an inlet and an outlet of the optical disc entering the avoiding channel, so that the optical disc reaches an optical disc destroying device such as an optical disc crusher and the like connected with the outside; when the optical disc is normally taken and placed, the optical disc storage position is located at the position corresponding to the loading position, and the second through hole 80 is shielded.

Preferably, the container driving device 53 drives the loading container to rotate, so as to switch the loading container corresponding to the loading position to be the optical disc destruction area 70 or the optical disc storage area 52.

The disc storage area 52 of this embodiment is further subdivided into a blank disc placement area and a recorded disc placement area.

The loading container is switched to the loading container corresponding to the loading position in a rotating manner, so that the structure of the CD-ROM drive mainboard assembly 40 is simplified to the greatest extent. In other embodiments, the optical disc drive motherboard assembly 40 may be provided with various mechanical structures to implement various motions, such as translation, lifting, etc., of the loading container, so as to switch the optical disc storage area 52 of the loading container corresponding to the loading position. In this embodiment, the rotation shaft is only required to be disposed in the feeding container, and the rotation shaft is connected to the output end of the container driving device 53 through the coupling, so that the feeding container can be driven to rotate, the structure of the optical drive motherboard assembly 40 is simple, and the movement track of the feeding container does not occupy other positions. In other embodiments, the container driving device 53 can drive the feeding container to rotate by using common means such as gear transmission according to practical applications.

In some preferred embodiments, the loading container is arranged in a regular pattern, such as a polygon like a square, a pentagon, etc., and the rotation center of the loading container is determined as the geometric center of the regular pattern, which is a preferred loading container arrangement scheme, the switching of the optical disc placement area can accurately correspond to the loading position of the moving member 11, so that deviation is not easy to occur, and the movement track of the loading container occupies the least space.

Preferably, the loading container comprises a disc 51 and a pudding barrel 52, wherein the pudding barrel 52 is arranged on the upper surface of the disc 51; the optical disc destruction area 70 is arranged on the upper surface part of the disc 51 without the pudding barrel 52, and the optical disc storage area 52 is arranged in the pudding barrel 52; the disc destruction area 70 and the pudding tub 52 are evenly distributed along the circumference of the disc 51; the container driving means 53 drives the disc 51 to rotate about the circular axis of the disc 51.

As shown in fig. 1 and 4, the disc 51 of the present embodiment is provided with 5 bunt buckets 52, the optical disc destruction device is a circular through hole having the same area as the bottom of a single bunt bucket 52, and the 5 bunt buckets 52 are uniformly distributed along the circumference of the disc 51, and the angle of each rotation of the disc 51 is not changed.

Specifically, ferry assembly 10 includes a vertical rail 12 and a ferry drive 13; the moving part 11 is driven by a ferry driving device 13 to move along a vertical guide rail 12; the vertical guide rail 12 is arranged on an axis, and the optical disc placing position after the first optical disc drive tray is ejected, the optical disc placing position after the second optical disc drive tray is ejected and the loading position are distributed on the axis.

Specifically, the moving member 11 includes a vacuum chuck 116 driving module and a vacuum chuck 116 module, and the vacuum chuck 116 driving module is connected with the vacuum chuck 116 module; the vacuum chuck 116 driving module comprises a mounting seat 111 and a negative pressure vacuum system; the vertical guide rail 12 and the negative pressure vacuum system are respectively connected with the mounting base 111; the vacuum chuck 116 module comprises a fixing part 112 and a plurality of guide posts 114 which are uniformly arranged and connected with the fixing part 112, one end of each guide post 114 is connected with the negative pressure vacuum system, the other end of each guide post is sequentially provided with a spring 115 and a chuck 116, one end of each spring 115 is connected with the fixing part 112, and the other end of each spring 115 is connected with the chuck 116; the vacuum system is connected to the fixing member 112 through a gasket 113, and the fixing member 112 and the gasket 113 are connected to the mounting seat 111, respectively.

The vacuum chuck 116 driving module drives the vacuum chuck 116 module, and acts on the vacuum chuck 116 module to enable the vacuum chuck 116 module to adsorb the optical disc, so as to realize the grabbing of the optical disc. The mounting seat 111 assembles all parts of the vacuum chuck 116 driving module and all parts of the vacuum chuck 116 module together, the moving part 11 integrally ascends and descends along the vertical guide rail 12, the moving part 11 descends to the position of the optical disk, and after grabbing is realized, the moving part 11 ascends and the optical disk leaves. The negative pressure vacuum system is used for generating negative pressure or vacuum, so that the vacuum chuck 116 module is placed under the negative pressure or vacuum, and the optical disk is adsorbed by the chuck 116.

The optical disks purchased in the market are usually packaged in the pudding barrels one by one, only the whole pudding barrel is required to be placed in the optical disk storage area 52 of the feeding container, the feeding container in which the vacuum sucker 116 module is matched with the motion can extract the optical disks stacked in the pudding barrels one by one, the optical disks do not need to be disassembled for split charging, and the pollution to the optical disks is reduced.

Specifically, the negative pressure vacuum system comprises a vacuum pump, an air seat 119 and a control processing system, wherein the air seat 119 is provided with an air suction port 117 and a plurality of air suction ports 118, the air suction port 117 is connected with the vacuum pump through an air pipe, the air suction ports 118 are connected with the guide column 114 through a vacuum pipeline, and the control processing system is connected with the vacuum pump; the control processing system comprises a pressure sensor, a bearing sensor, an electromagnetic valve and a control processor, wherein the pressure sensor is connected with the control processor and a vacuum pipeline, and the weighing sensor, the electromagnetic valve and the vacuum pump are respectively connected with the control processor.

Preferably, the control processing system of this embodiment includes pressure sensor, load-bearing sensor, solenoid valve and control processor, and pressure sensor is connected with control processor and vacuum pipe, and weighing sensor, solenoid valve and vacuum pump are connected with control processor respectively.

The control processing system is used for controlling the vacuum pump to act on the vacuum pipeline, when the moving part 11 descends until the sucker 116 contacts with the optical disk, the elastic force of the spring 115 urges the sucker 116 to elastically abut against the surface of the optical disk, and the control processing system controls the vacuum pump to start, act on the vacuum pipeline, and enable the sucker 116 and the optical disk protective coating to be in the same plane along the pumping hole 117, the air seat 119, the air suction hole 118 and the guide column 114, so as to adsorb the optical disk. The control processing system comprises a pressure sensor, an electromagnetic valve and a control processor, the pressure sensor is connected with the control processor and the vacuum pipeline, and the weighing sensor, the electromagnetic valve and the vacuum pump are respectively connected with the control processor.

When the moving part 11 descends to the position where the weighing sensor senses the optical disc, the control processor transmits a signal to the electromagnetic valve, the valve of the electromagnetic valve is opened, the electromagnetic valve starts acting on the vacuum pump, the vacuum pump starts, the sucking disc 116 is enabled to adsorb the optical disc, meanwhile, the descending speed is adjusted, and the sucking disc 116 is matched to adsorb the optical disc. Meanwhile, the mechanical lifting mechanism adjusts the descending speed to cooperate with the sucker 116 to absorb the optical disk. After the suction cup 116 finishes the absorption of the optical disc, the control processor acts on the pressure sensor, and compares the pressure value displayed by the pressure sensor with the set value to determine whether the optical disc is successfully absorbed on the suction cup 116. If the pressure value displayed by the pressure sensor is higher than the set value, which indicates that the optical disc is not successfully adsorbed on the suction cup 116, the control processor acts on the electromagnetic valve, the valve is kept in an open state, and the adsorption is continued until the adsorption is successful, so that the pressure value displayed by the pressure sensor is equal to or lower than the set value. If the pressure value displayed by the pressure sensor is equal to or lower than the set value, indicating that the optical disc is successfully adsorbed on the suction cup 116, at this time, the moving member 11 is lifted, and the optical disc leaves, completing the grabbing of the optical disc. The control processor receives the command and transmits the command to the electromagnetic valve, the electromagnetic valve is closed, at this time, the optical disk is not adsorbed by the sucking disk 116 any more, and the optical disk is put down. And repeating the steps, and continuing to grab the next optical disk.

Preferably, a control module 60 is also included, the control module 60 including: the system comprises a touch screen, a PLC (programmable logic controller), a tray ejection state detection sensor of a network A optical drive 20, a tray ejection state detection sensor of a network B optical drive 30, a horizontal sensor and a vertical sensor; the touch screen is used for issuing a control instruction; the tray popup state detection sensor of the A-network optical drive 20 detects whether a first optical drive tray corresponding to the A-network optical drive 20 is in a popup state; the tray popup state detection sensor of the B-network optical drive 30 detects whether a second optical drive tray corresponding to the B-network optical drive 30 is in a popup state; the horizontal sensor and the vertical sensor jointly detect whether the optical drive main board assembly 40 is at a preset position; the PLC controller controls the ferry component 10, the A-network optical drive 20, the B-network optical drive 30 and the optical drive mainboard component 40 through the tray ejection state detection sensor of the A-network optical drive 20, the tray ejection state detection sensor of the B-network optical drive 30, the vertical sensor, the horizontal sensor and the feedback information of the moving part 11.

Preferably, the number of ferry assemblies 10 is at least two; the number of the network A optical drives 20 and the number of the network B optical drives 30 are the same as that of the ferry component 10, and the network A optical drives 20, the network B optical drives 30 and the ferry component 10 are arranged in a one-to-one manner; the different ferry assemblies 10 have different loading positions; the optical disc drive main board assembly 40 connects all the network a optical disc drives 20 and the network B optical disc drives 30.

The arrangement of at least two ferry assemblies 10 has two functions, one is to ensure the working operation of the optical disk ferry device when a single ferry assembly 10 fails, and the other is to improve the upper limit of ferry efficiency, and when the data volume to be processed is large, a plurality of ferry assemblies 10 can be started at the same time. Each ferry component 10 has a respective feeding position, the feeding position of each ferry component 10 in this embodiment is the lowest end of the respective vertical guide rail 12, one feeding position is located above one pudding bucket 52 or first through hole 70 on the disc 51, corresponds to one pudding bucket 52 or first through hole 70, the disc 51 is controlled to rotate, cooperate with the moving part 11 for picking and placing optical discs up and down, so as to orderly perform the operation of one or more ferry components 10, the moving range of the moving part 11 is small, and the internal space of the optical disc ferry device is saved.

It should be understood that the above-mentioned embodiments of the present invention are only examples for clearly illustrating the technical solutions of the present invention, and are not intended to limit the specific embodiments of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention claims should be included in the protection scope of the present invention claims.

Claims (10)

1. An optical disk ferrying device with a destruction function, comprising: the device comprises a shell, a feeding module, a network A optical drive, a network B optical drive, an optical drive mainboard assembly and a ferry assembly; the loading module is used for storing the optical disk; the A-network optical drive acquires an optical disk by popping up a first optical drive tray and records the optical disk; the B-network optical drive acquires the optical disk by popping up a second optical drive tray and reads the optical disk; the ferry component is used for moving the optical disk among the feeding module, the network A optical drive and the network B optical drive; it is characterized in that the preparation method is characterized in that,

the ferry assembly comprises a moving part;

the moving piece moves to a fixed loading position, and the optical disk is grabbed from the loading module or is stored back to the loading module at the loading position;

the feeding module comprises a feeding container and a container driving device;

the feeding container is divided into an optical disc destroying area and an optical disc storage area;

the container driving device drives the feeding container to move so as to switch the feeding container corresponding to the feeding position into an optical disk destroying area or an optical disk storage area.

2. The optical disk ferrying device with destruction function according to claim 1,

the optical disc destroying area is a first through hole on the feeding container;

a destroying part is arranged at the bottom of the shell corresponding to the feeding position;

when the feeding container corresponding to the feeding position is switched to the first through hole, the optical disc to be destroyed can pass through the through hole to reach the destruction part.

3. The optical disk ferrying device with destruction function according to claim 2,

the destroying part is a second through hole at the bottom of the shell and is used for connecting the optical disc destroying device;

when the feeding container corresponding to the feeding position is switched to the first through hole, the first through hole is aligned to the second through hole to form an avoiding channel, so that the optical disc to be destroyed passes through the avoiding channel to reach the optical disc destroying device.

4. The optical disk ferrying device with destruction function according to claim 1,

the container driving device drives the feeding container to rotate so as to switch the feeding container corresponding to the feeding position into an optical disk destruction area or an optical disk storage area.

5. The optical disk ferrying device with destruction function according to claim 4,

the feeding container comprises a disc and a pudding barrel, and the pudding barrel is arranged on the upper surface of the disc;

the optical disk destroying area is arranged on the upper surface part of the disk, which is not provided with the pudding barrel, and the optical disk storage area is arranged in the pudding barrel; the optical disc destroying area and the pudding barrel are uniformly distributed along the circumference of the disc;

the container driving device drives the circular disc to rotate around the circular mandrel of the circular disc.

6. The optical disk ferrying device with destruction function according to claim 1,

the ferry assembly comprises a vertical guide rail and a ferry driving device;

the moving part is driven by the ferry driving device to move along the vertical guide rail;

the vertical guide rail is arranged on an axis, and the optical disc placing position after the first optical disc drive tray is popped out, the optical disc placing position and the material loading position after the second optical disc drive tray is popped out are distributed on the axis.

7. The optical disk ferrying device with destruction function according to claim 6,

the moving piece comprises a vacuum chuck driving module and a vacuum chuck module, and the vacuum chuck driving module is connected with the vacuum chuck module;

the vacuum chuck driving module comprises a mounting seat and a negative pressure vacuum system;

the vertical guide rail and the negative pressure vacuum system are respectively connected with the mounting base;

the vacuum sucker module comprises a fixing piece and a plurality of guide posts which are connected with the fixing piece and are uniformly arranged, one ends of the guide posts are connected with the negative pressure vacuum system, the other ends of the guide posts are sequentially provided with a spring and a sucker, one end of the spring is connected with the fixing piece, and the other end of the spring is connected with the sucker;

the negative pressure vacuum system is connected with the fixing piece through a gasket, and the fixing piece and the gasket are respectively connected with the mounting seat.

8. The optical disk ferrying device with destruction function according to claim 7,

the negative pressure vacuum system comprises a vacuum pump, an air seat and a control processing system, wherein the air seat is provided with an air suction port and a plurality of air suction ports, the air suction port is connected with the vacuum pump through an air pipe, the air suction ports are connected with the guide columns through vacuum pipelines, and the control processing system is connected with the vacuum pump;

the control processing system comprises a pressure sensor, a bearing sensor, an electromagnetic valve and a control processor, wherein the pressure sensor is connected with the control processor and a vacuum pipeline, and the weighing sensor, the electromagnetic valve and the vacuum pump are respectively connected with the control processor.

9. The optical disk ferrying device with destruction function according to claim 1,

still include control module, control module includes: the system comprises a touch screen, a PLC (programmable logic controller), an A-network CD-ROM drive tray pop-up state detection sensor, a B-network CD-ROM drive tray pop-up state detection sensor, a horizontal sensor and a vertical sensor;

the touch screen is used for issuing a control instruction;

the A-network CD driver tray popup state detection sensor detects whether a first CD driver tray corresponding to the A-network CD driver is in a popup state; the B-network optical drive tray popup state detection sensor detects whether a second optical drive tray corresponding to the B-network optical drive is in a popup state;

the horizontal sensor and the vertical sensor jointly detect whether the feeding module is at a preset position;

the PLC controller controls the ferry component, the A-net CD driver, the B-net CD driver and the feeding module through feedback information of the A-net CD driver tray ejection state detection sensor, the B-net CD driver tray ejection state detection sensor, the vertical sensor, the horizontal sensor and the moving part.

10. The optical disk ferrying device with a destruction function according to any one of claims 1 to 9,

the number of the ferry components is at least two; the number of the network A optical drives and the number of the network B optical drives are the same as that of the ferry components, and the network A optical drives, the network B optical drives and the ferry components are arranged in a one-to-one manner;

the material loading positions of different ferry assemblies are different;

the CD-ROM main board component is connected with all the A-network CD-ROM drives and the B-network CD-ROM drives.

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