CN219738543U - Video monitoring automatic storage device - Google Patents

Abstract

The utility model discloses an automatic storage device for video monitoring, and relates to the technical field of storage devices. Comprising the following steps: the storage hard disk is electrically connected with the video monitoring, one end of the top of the storage hard disk is provided with a carrying groove, and a data groove is arranged in the carrying groove; a linkage assembly is arranged at the end of the bottom of the storage hard disk; the linkage assembly includes: the bottom of the sliding block is fixedly provided with a stress arm extending outwards, and one side of the sliding block is fixedly provided with an electronic board; a telescopic plug is fixed at one surface of the electronic board, which is far away from the sliding block, the telescopic plug is matched with the data slot, and a tensile wire harness for transmitting data is arranged between the input end of the electronic board and the storage hard disk. According to the utility model, the linkage assembly capable of being overlapped is additionally arranged on the common storage hard disk, so that the device can be combined and additionally arranged at will to expand the memory in actual use, and the flexibility of the device in use is improved to a certain extent.

Description

Video monitoring automatic storage device

Technical Field

The utility model relates to the technical field of storage devices, in particular to an automatic video monitoring storage device.

Background

At present, video monitoring which is promoted in a large area is divided into two types, one type is that a camera monitors a place needing to be monitored, and meanwhile, a monitoring picture is sent to a monitoring room, and a special person looks at the monitoring picture; the second is to store the monitor picture for 24 hours by using the memory card, and call out the corresponding video data when necessary.

The utility model of China with the authorized bulletin number of CN204069174U discloses an automatic video monitoring storage device, and the application provides the prior art problem that the memory requirement of a memory card is high in the prior art, so that a storage hard disk is additionally arranged in the video monitoring device on the market for increasing the storage capacity.

When the number of hard disk cartridges in the video monitoring device is small or the capacity is maximized, the capacity expansion cannot be realized.

Disclosure of Invention

The present utility model is directed to an automatic video surveillance storage device, so as to solve the problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: video monitoring automatic storage device includes:

a storage hard disk electrically connected with the video monitoring,

a carrying groove is formed in one end of the top of the storage hard disk, and a data groove is formed in the carrying groove;

a linkage assembly is arranged at one end of the bottom of the storage hard disk, which is provided with a carrying groove;

the linkage assembly includes:

the bottom of the sliding block is fixedly provided with a stress arm extending outwards, and one side of the sliding block is fixedly provided with an electronic board;

a telescopic plug is fixed at one surface of the electronic board, which is far away from the sliding block, the telescopic plug is matched with the data slot, and a tensile wire harness for transmitting data is arranged between the input end of the electronic board and the storage hard disk.

Furthermore, inserting grooves are respectively formed in the periphery of the top of the storage hard disk;

plug pins are respectively fixed on the periphery of the bottom of the storage hard disk;

the plug pins are matched with the plug grooves.

Furthermore, a magnetic chuck is fixed at one end of the top of the storage hard disk far away from the carrying groove;

a metal block is fixed at one end of the bottom of the storage hard disk far away from the sliding block,

the metal block can be adsorbed by the magnetic chuck.

Furthermore, the input end of the storage hard disk is a socket groove arranged at one end of the outside of the storage hard disk far away from the carrying groove, and a data socket for externally connecting storage equipment is formed on one side of the outside of the storage hard disk;

the output end of the video monitoring is a communication plug;

the communicating plug is matched with the socket groove.

Further, a sliding groove matched with the sliding block is formed in the bottom of the storage hard disk, and the sliding block is arranged in the sliding groove;

the bottom of the storage hard disk is also provided with an assembly groove at two sides of the sliding groove, and a communication notch for communication is arranged between the assembly groove and the sliding groove;

the inside of the assembly groove is provided with a damper, the output end of the damper faces the stress arm, a connecting ring is fixed outside the output end of the damper, a connecting rod is fixed outside the connecting ring, and one end of the connecting rod is fixed outside the sliding block through a communication notch.

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

according to the video monitoring automatic storage device, the linkage component capable of being overlapped is additionally arranged on the common storage hard disk, so that the device can be combined and additionally arranged at will to expand the memory in actual use, and the flexibility of the device in use is improved to a certain extent;

meanwhile, the magnetic chuck arranged at the top of the storage device and the metal block arranged at the bottom of the storage device are in adsorption fit, so that the stability of the storage device in a superposition state is enhanced.

Drawings

FIG. 1 is an isometric view of the present utility model;

FIG. 2 is a bottom structural component view of the present utility model;

FIG. 3 is an enlarged view of a portion A of FIG. 2;

fig. 4 is an actual assembly view of the present utility model.

In the figure: 1. storing a hard disk; 2. a plug-in groove; 3. a linkage assembly; 301. a force receiving arm; 302. a sliding block; 303. an electronic board; 304. a sliding groove; 305. stretching the wire harness; 306. a damper; 307. a communicating notch; 308. a retractable plug; 4. a carrying groove; 5. a data slot; 6. a magnetic chuck; 7. a communication plug; 8. a socket slot; 9. a data jack; 10. a plug pin; 11. a metal block.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

At present, video monitoring which is promoted in a large area is divided into two types, one type is that a camera monitors a place needing to be monitored, and meanwhile, a monitoring picture is sent to a monitoring room, and a special person looks at the monitoring picture; the second is to store the monitor picture for 24 hours by using the memory card, and call out the corresponding video data when needed.

To this end the applicant proposes a new device.

Referring to fig. 1 to 4, the apparatus includes:

a storage hard disk 1 electrically connected with the video monitoring,

a carrying groove 4 is formed in one end of the top of the storage hard disk 1, and a data groove 5 is formed in the carrying groove 4;

a linkage assembly 3 is arranged at one end of the bottom of the storage hard disk 1, which is provided with a carrying groove 4;

the linkage assembly 3 includes:

the bottom of the sliding block 302 is fixed with a stress arm 301 extending outwards, and one side of the sliding block 302 is fixed with an electronic board 303;

a telescopic plug 308 is fixed at one surface of the electronic board 303 far away from the sliding block 302, the telescopic plug 308 is matched with the data slot 5, and a stretching wire harness 305 for transmitting data is arranged between the input end of the electronic board 303 and the storage hard disk 1.

It is emphasized that the linkage component 3 capable of being overlapped is additionally arranged on the common storage hard disk 1, so that the device can be combined and additionally arranged at will to expand the memory in actual use, and the flexibility of the device in use is improved to a certain extent; meanwhile, the magnetic chuck 6 arranged at the top of the storage device and the metal block 11 arranged at the bottom of the storage device are in adsorption fit, so that the stability of the storage device in a superposition state is enhanced.

The single storage hard disk 1 of the present device is provided with a plurality of functional interfaces including: socket slot 8, telescoping plug 308, data slot 5. The socket groove 8 is connected with the communication plug 7 in an adaptive manner and is connected with the data input terminal through the communication plug 7; the retractable plug 308 on one storage hard disk 1 can be connected with the data slot 5 on the other storage hard disk 1 in a matching way for power supply and data transmission.

When a plurality of storage hard disks 1 are stacked and combined, power supply and data transmission are performed between two adjacent storage hard disks 1 through the matched telescopic plug 308 and the data groove 5, so that the plurality of storage hard disks 1 are connected in series. The plurality of storage hard disks 1 are mutually overlapped to form a hard disk group together, and all the hard disk information can be read by the socket grooves 8 on any storage hard disk 1, so that the hard disk group is powered and data transmitted through the single communication plug 7. The number of storage hard disks 1 needs to be controlled within the line bearing range, only because of the limited power and data capabilities of the individual lines.

After accessing the data input terminal, the storage hard disks 1 in the hard disk group are identified one by one, and are represented as a plurality of disk symbols in the terminal, or are formed into a hard disk array in a RAID form, and are displayed as one disk symbol in the terminal. The former can read and write any hard disk, so that the classification and induction of data are convenient, and the number of the hard disks can be increased or decreased at will. The latter forms the hard disk array in RAID0 form and can obtain higher read-write speed, and forms the hard disk array in RAIDn (n=1, 2, 3.) form and can obtain higher fault-tolerant rate, guarantee information security. However, after RAID is formed, the number of hard disks cannot be increased or decreased at will, a conventional computer does not have enough space for placing a plurality of hard disks, and also has no enough interfaces for supporting hard disk connection, so that the device can be externally arranged and can be mutually overlapped, and convenient information storage and maintenance can be performed.

Embodiment 1,

As can be seen with reference to fig. 1 and 2, in the present utility model,

the periphery of the top of the storage hard disk 1 is respectively provided with a splicing groove 2;

plug pins 10 are respectively fixed on the periphery of the bottom of the storage hard disk 1;

the plug pins 10 are matched with the plug grooves 2.

It should be noted that the present embodiment is characterized in order to enhance the stability of the storage hard disk 1 when stacked.

Embodiment II,

As can be seen with reference to fig. 1 and 2, the device comprises:

a magnetic chuck 6 is fixed at one end of the top of the storage hard disk 1 far away from the carrying groove 4;

a metal block 11 is fixed at one end of the bottom of the storage hard disk 1 far from the sliding block 302,

the metal block 11 can be attracted by the magnetic chuck 6.

Third embodiment,

The input end of the storage hard disk 1 is a socket groove 8 arranged at one end of the outside of the storage hard disk 1 far away from the carrying groove 4, and a data socket 9 for externally connecting storage equipment is formed on one side of the outside of the storage hard disk 1, so that the data of the storage hard disk 1 can be read independently without disassembly;

the output end of the video monitoring is a communication plug 7;

the communication plug 7 is matched with the socket groove 8.

It should be noted that the present embodiment is characterized in order to enhance the stability of the storage hard disk 1 when stacked.

Fourth embodiment,

Referring to FIG. 3, in the present utility model, a sliding groove 304 is formed at the bottom of the storage hard disk 1 and is matched with a sliding block 302, and the sliding block 302 is disposed in the sliding groove 304; the bottom of the storage hard disk 1 is also provided with assembly grooves on two sides of the sliding groove 304, and a communication notch 307 for communication is arranged between the assembly grooves and the sliding groove 304; the damper 306 is installed in the assembly groove, the output end of the damper 306 faces the force receiving arm 301, a connecting ring is fixed outside the output end of the damper 306, a connecting rod is fixed outside the connecting ring, and one end of the connecting rod is fixed with the outer part of the sliding block 302 through the communication notch 307.

It should be added that, when the device is actually used, the sliding block 302 moves in the sliding groove 304 through the force receiving arm 301, the telescopic plug 308 is in a compressed state first, and when the telescopic plug 308 just reaches the data groove 5, the telescopic plug 308 rebounds in the data groove 5, and the storage hard disk 1 is limited.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made hereto without departing from the spirit and scope of the utility model as defined by the appended embodiments and equivalents thereof.

Claims (5)

1. Video monitoring automatic storage device, its characterized in that includes:

a storage hard disk (1) electrically connected with the video monitoring,

a carrying groove (4) is formed in one end of the top of the storage hard disk (1), and a data groove (5) is formed in the carrying groove (4);

a linkage assembly (3) is arranged at one end of the carrying groove (4) arranged at the bottom of the storage hard disk (1);

the linkage assembly (3) comprises:

the electronic device comprises a sliding block (302), wherein a stress arm (301) extending outwards is fixed at the bottom of the sliding block, and an electronic board (303) is fixed at one side of the sliding block (302);

a telescopic plug (308) is fixed at one surface of the electronic board (303) far away from the sliding block (302), the telescopic plug (308) is matched with the data groove (5), and a tensile wire harness (305) for transmitting data is arranged between the input end of the electronic board (303) and the storage hard disk (1).

2. The video surveillance automatic storage device of claim 1, wherein:

the periphery of the top of the storage hard disk (1) is respectively provided with a splicing groove (2);

plug pins (10) are respectively fixed on the periphery of the bottom of the storage hard disk (1);

the plug pins (10) are matched with the plug grooves (2).

3. The video surveillance automatic storage device of claim 1, wherein:

a magnetic chuck (6) is fixed at one end of the top of the storage hard disk (1) far away from the carrying groove (4);

a metal block (11) is fixed at one end of the bottom of the storage hard disk (1) far away from the sliding block (302),

the metal block (11) can be adsorbed by the magnetic chuck (6).

4. The video surveillance automatic storage device of claim 1, wherein:

the input end of the storage hard disk (1) is a socket groove (8) arranged at one end of the outside of the storage hard disk, which is far away from the carrying groove (4), and a data socket (9) for externally connecting storage equipment is formed on one side of the outside of the storage hard disk (1);

the output end of the video monitoring is a communication plug (7);

the communication plug (7) is matched with the socket groove (8).

5. The video surveillance automatic storage device of claim 1, wherein:

a sliding groove (304) matched with the sliding block (302) is formed in the bottom of the storage hard disk (1), and the sliding block (302) is arranged in the sliding groove (304);

the bottom of the storage hard disk (1) is also provided with an assembly groove at two sides of the sliding groove (304), and a communication notch (307) for communication is arranged between the assembly groove and the sliding groove (304);

the inside of the assembly groove is provided with a damper (306), the output end of the damper (306) faces the stress arm (301), a connecting ring is fixed outside the output end of the damper (306), a connecting rod is fixed outside the connecting ring, and one end of the connecting rod is fixed outside the sliding block (302) through a communication notch (307).