CN114151662A

CN114151662A - Mobile intelligent safety monitoring equipment

Info

Publication number: CN114151662A
Application number: CN202111486222.5A
Authority: CN
Inventors: 谢飞; 邓罗文; 熊海波
Original assignee: Ambrera Shenzhen Intelligent Technology Co ltd
Current assignee: Ambrera Shenzhen Intelligent Technology Co ltd
Priority date: 2021-12-07
Filing date: 2021-12-07
Publication date: 2022-03-08
Anticipated expiration: 2041-12-07
Also published as: CN116255534A; CN114151662B

Abstract

The invention relates to the technical field of construction safety equipment, in particular to mobile intelligent safety monitoring equipment. The device comprises a transport box, an upper cover, a bracket connecting unit, a bracket unit and a network high-definition distribution control holder; the top of the transport box is of an open structure, and one side of the upper cover is hinged to the edge of one side of the top of the transport box; the bracket connecting unit is arranged in the transport box and comprises a first telescopic rod and a bracket mounting plate; one end of the first telescopic rod is hinged to the connecting column, the other end of the first telescopic rod is fixedly connected with the support mounting plate, and the central axis of the support mounting plate is superposed with the central axis of the first telescopic rod; the support mounting panel is close to a lateral wall edge department of first telescopic link the axis of first telescopic link is central, and it has a plurality of groups second telescopic links to be articulated to be annular array, three groups are no less than to the quantity of second telescopic link. The invention can improve the shooting quality of the network high-definition distribution control cloud deck.

Description

Mobile intelligent safety monitoring equipment

Technical Field

The invention belongs to the technical field of construction safety equipment, and particularly relates to mobile intelligent safety monitoring equipment.

Background

Construction can involve many aspects of safe construction management, and at present, the safety supervision of a construction site is usually completed through special supervision equipment.

The monitoring apparatus is generally classified into a mobile type and a stationary type, wherein the mobile type is widely used due to advantages such as convenience in installation. Nowadays, with the progress of science and technology, the monitoring equipment is also developed more and more in an intelligent direction. The monitoring scheme is mainly characterized in that image acquisition is carried out on a construction site through a network deployment cloud platform, and then image information is transmitted to a main control end through an industrial gateway, so that monitoring personnel can realize real-time monitoring without going to the construction site.

The movable network distribution cloud platform is usually fixed by a support unit, and because the whole volume of the support unit is small, and the working site of the network distribution cloud platform is usually in an outdoor construction site, under the influence of environmental factors, the network distribution cloud platform is very easy to be interfered by external force, so that the support unit is sent to shake or even obliquely turn on the side, the stability of the network distribution cloud platform is directly influenced, and the shooting quality is reduced.

Disclosure of Invention

Aiming at the problems, the invention provides mobile intelligent safety monitoring equipment which comprises a transport box, an upper cover, a bracket connecting unit, a bracket unit and a network high-definition distribution control holder; the top of the transport box is of an open structure, and one side of the upper cover is hinged to the edge of one side of the top of the transport box; the bracket connecting unit is arranged in the transport box and comprises a first telescopic rod and a bracket mounting plate; one end of the first telescopic rod is hinged to the connecting column, the other end of the first telescopic rod is fixedly connected with the support mounting plate, and the central axis of the support mounting plate is superposed with the central axis of the first telescopic rod; the bracket mounting plate is close to one side wall edge of the first telescopic rod, takes the central axis of the first telescopic rod as the center, and is hinged with a plurality of groups of second telescopic rods in an annular array, and the number of the second telescopic rods is not less than three; the network high-definition distribution and control cloud deck can be movably arranged on the bracket mounting plate; and an industrial gateway is installed in the transport box and is electrically connected with the network high-definition distribution control holder.

Furthermore, a storage battery is arranged in the transport box and is electrically connected with the support unit and the industrial gateway respectively.

Further, a foam block is fixedly installed in the transport box, a support limiting groove is formed in the top of the foam block, and one end, close to the support unit, of the support limiting groove is of an open structure; the bracket unit can be movably inserted into the bracket limiting groove; an equipment limiting groove is formed in one side of the support limiting groove, and the network high-definition distribution control holder can be movably inserted into the equipment limiting groove.

Furthermore, the monitoring equipment also comprises two groups of damping units, wherein each damping unit comprises a silica gel block; the two groups of silica gel blocks are respectively and fixedly installed at the corners of the bottoms of the outer walls of the two sides of the transport box, and a damping inner cavity is formed in each silica gel block; a plurality of groups of first buffer strips are distributed in the shock absorption inner cavity at equal intervals, two ends of each first buffer strip are respectively installed on two side walls of the shock absorption inner cavity parallel to the transportation box, and the first buffer strips are of a corrugated structure.

Further, the bracket connecting unit comprises a connecting column base and a connecting column; the connecting column base is arranged in the transport box; the top of the connecting column base is provided with an annular groove, the connecting column is installed in the annular groove, and the central axis of the connecting column is superposed with the central axis of the annular groove; and a plurality of groups of reset springs are distributed on the outer wall of the connecting column in an annular array, and the other ends of the reset springs are respectively arranged on the inner walls around the annular groove.

Furthermore, one end of the bracket unit is hinged to the connecting column, a bracket clamping block is fixedly mounted on the outer wall of one side, close to the bracket limiting groove, of the connecting column, and the bracket clamping block is located right above the joint of the bracket unit and the connecting column; the output end of the bracket unit can be movably clamped on the bracket clamping block.

Further, the holder unit further includes a rotation motor; the rotary motor is fixedly installed on a side wall, away from the first telescopic link, of the support mounting plate, and the network high-definition distribution control holder is movably clamped on the output end of the rotary motor.

Further, the first telescopic rod comprises an outer sleeve rod; the outer sleeve rod can be movably clamped on the bracket clamping block; one end of the outer sleeve rod is hinged to the connecting column, and the other end of the outer sleeve rod is provided with a telescopic groove.

Furthermore, the first telescopic rod also comprises a lifting rod; one end of the lifting rod is located in the telescopic groove, and the other end of the lifting rod can movably penetrate through the outside of the telescopic groove and is fixedly connected with the support mounting plate.

Further, fixed mounting has equipment socket on the lifter is close to the one end lateral wall of support mounting panel, equipment socket can with network high definition cloth accuse cloud platform electric connection.

The invention has the beneficial effects that:

1. through the joint relation between first telescopic link and the spliced pole for the whole casing of support unit is fixed on the transport box. Then the self weight of the transportation box and the weight of the balance block are utilized to increase the stability of the support unit, and therefore the anti-interference capability of the network high-definition distribution control holder during working is improved.

2. When the support unit is influenced by external force, the connecting column can be driven to displace, and then the connecting column can transmit the external force to the reset springs distributed in the annular array. Utilize reset spring's elasticity to offset external force to make the spliced pole get back to the normal position, avoid network high definition to distribute accuse cloud platform because of displacement or vibrations influence the shooting effect, thereby improved the operating mass with rated load of network high definition cloth accuse cloud platform.

3. When the network high-definition distribution and control holder works, firstly, a plug of the network high-definition distribution and control holder is plugged into an equipment socket, and then the electric energy of the storage battery is transmitted to the network high-definition distribution and control holder by utilizing the electric wire bodies which are arranged in the outer loop bar and the lifting rod. The power supply of the network high-definition distribution control holder is not required to be additionally realized by using the open line, so that the convenience of equipment use is improved.

4. When the transport box is impacted in the moving process, part of the impact force is firstly absorbed by the outer wall of the silica gel block, and the residual impact force is transmitted to one group or a plurality of groups of first buffer strips corresponding to the impact points. Due to the characteristics of the corrugated structure of the first buffer strip, the elastic force of the first buffer strip is increased. Thus, when an impact force acts on a first bumper strip, it is substantially absorbed by the first bumper strip, and the remaining impact force is transferred to the other sets of first bumper strips through the second bumper strip. The impact force received by the transport box is avoided, and the shock absorption of the transport box is improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.

Fig. 1 shows a schematic structural diagram of an inspection apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of the monitoring device according to the embodiment of the invention after being stored;

FIG. 3 shows a schematic cross-sectional view of an inspection apparatus according to an embodiment of the invention after storage;

FIG. 4 shows a schematic structural view of a transport pod according to an embodiment of the present invention;

FIG. 5 shows a schematic cross-sectional view of a damping unit according to an embodiment of the invention;

FIG. 6 shows a schematic top view of a stent connection unit according to an embodiment of the present invention;

FIG. 7 shows a schematic structural diagram of a rack unit according to an embodiment of the invention;

FIG. 8 shows a cross-sectional schematic view of a first telescoping pole according to an embodiment of the invention;

fig. 9 is a schematic end-sectional view of a power line module according to an embodiment of the invention.

In the figure: 100. a transport box; 110. a foam block; 120. a bracket limiting groove; 130. an equipment limiting groove; 200. an upper cover; 210. a limiting foam board; 300. a storage battery; 400. a damping unit; 410. a silica gel block; 420. a shock-absorbing inner cavity; 430. a first buffer strip; 440. a second buffer bar; 500. a bracket connection unit; 510. a connecting column base; 520. an annular groove; 530. connecting columns; 540. a return spring; 550. a bracket clamping block; 600. a holder unit; 610. a first telescopic rod; 611. an outer loop bar; 612. a telescopic groove; 613. a lifting rod; 614. an electric wire mounting groove; 615. fixing a rod by a wire coil; 616. an equipment receptacle; 617. a wire coil body; 620. a bracket mounting plate; 630. a rotary motor; 640. a second telescopic rod; 650. a power line module; 651. an outer insulating sleeve; 652. a wire body; 653. a clockwork spring; 700. a counterbalance; 800. network high definition accuse cloud platform.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. 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.

The embodiment of the invention provides mobile intelligent safety monitoring equipment. The system comprises a transport box 100, an upper cover 200, a bracket connecting unit 500, a bracket unit 600 and a network high-definition distribution control holder 800. Illustratively, as shown in fig. 1, 2 and 3, the top of the transportation box 100 is an open structure, one side of the upper cover 200 is hinged at the edge of one side of the top of the transportation box 100, and the other side of the upper cover 200 is movably clamped with the transportation box 100.

The storage battery 300 is disposed in the transportation box 100, and the bracket connection unit 500 is located above the storage battery 300.

One end of the stand unit 600 is hinged to the stand connection unit 500, and the stand unit 600 is electrically connected to the battery 300. The support unit 600 is used for supporting the network high-definition distribution control holder 800.

An industrial gateway is fixedly installed in the transportation box 100, and the industrial gateway is electrically connected with the storage battery 300 and the network high-definition distribution control holder 800 respectively. The industrial gateway is used for providing wireless network connection for the network high-definition distribution control holder 800.

A group of damping units 400 are respectively arranged at the edges of two sides of the bottom of the outer wall of the transportation box 100. The transport box 100 can be prevented from being damaged by an external force by the shock-absorbing unit 400.

The output end of the rack unit 600 can movably penetrate through the outside of the transportation box 100. The network high-definition control cloud deck 800 is movably clamped at the output end of the support unit 600.

For example, as shown in fig. 4, a foam block 110 is fixedly installed in the transportation box 100, a bracket limiting groove 120 is formed at the top of the foam block 110, and one end of the bracket limiting groove 120, which is close to the bracket unit 600, is an open structure. The holder unit 600 is movably inserted into the holder limiting groove 120. An equipment limiting groove 130 is formed in one side of the support limiting groove 120, and the network high-definition distribution control holder 800 can be movably inserted into the equipment limiting groove 130. A balance weight 700 is fixedly mounted on the inner wall of the bottom of the transportation box 100.

Preferably, a limiting foam plate 210 is fixedly installed in the inner cavity of the upper cover 200, and the limiting foam plate 210 is movably attached to the top of the foam block 110.

When equipment was idle, accomodate back grafting at support spacing groove 120 with support element 600 to with network high definition cloth accuse cloud platform 800 from the output of support element 600 on dismantle, and plug in equipment spacing groove 130, for support element 600 and network high definition cloth accuse cloud platform 800 provide the protection through foam piece 110, prevent to cause the injury because of external force to support element 600 and network high definition cloth accuse cloud platform 800.

At the same time, the use of the weight 700 increases the stability of the transport box 100.

The shock absorbing unit 400 includes a silica gel block 410. For example, as shown in fig. 5, the silicone block 410 is fixedly installed at a bottom corner of the outer wall of the transportation box 100, and a shock absorbing cavity 420 is formed in the silicone block 410. A plurality of groups of first buffer strips 430 are distributed in the shock absorption inner cavity 420 at equal intervals, two ends of each first buffer strip 430 are respectively installed on two side walls of the shock absorption inner cavity 420, which are parallel to the transportation box 100, and each first buffer strip 430 is of a corrugated structure. A plurality of groups of second buffer strips 440 are fixedly arranged between two adjacent groups of first buffer strips 430.

When the transport box 100 collides during movement, it first contacts the outer wall of the silicone block 410, and then absorbs a part of the collision force by using the outer wall of the silicone block 410 and transmits the remaining collision force to one or more groups of the first buffer strips 430 corresponding to the collision points. The elastic force of the first buffer strip 430 is increased due to the characteristics of the corrugated structure of the first buffer strip 430. Therefore, when an impact force acts on the first buffer bar 430, it is substantially absorbed by the first buffer bar 430, and the remaining impact force is transferred to the other groups of the first buffer bars 430 through the second buffer bars 440. The shipping box 100 is prevented from receiving the impact force, and thus the shock-absorbing property of the shipping box 100 is improved.

The bracket coupling unit 500 includes a coupling post base 510 and a coupling post 530. Illustratively, as shown in fig. 6, the connecting column base 510 is fixedly installed in the transportation box 100, and the connecting column base 510 is located at one side of the bracket limiting groove 120 close to the opening. An annular groove 520 is formed in the top of the connecting column base 510, the connecting column 530 is fixedly installed in the annular groove 520, and the central axis of the connecting column 530 coincides with the central axis of the annular groove 520. A plurality of groups of reset springs 540 are distributed on the outer wall of the connecting column 530 in an annular array, and the other ends of the plurality of groups of reset springs 540 are respectively and fixedly installed on the peripheral inner wall of the annular groove 520. One end of the bracket unit 600 is hinged to the connection column 530, a bracket clamping block 550 is fixedly mounted on the outer wall of one side of the connection column 530 close to the bracket limiting groove 120, and the bracket clamping block 550 is positioned right above the joint of the bracket unit 600 and the connection column 530. The output end of the holder unit 600 is movably clamped on the holder clamping block 550.

Before the device is used, the rack unit 600 is taken out of the rack limiting groove 120 and clamped on the rack clamping block 550. Then, the cradle unit 600 is opened, and the network high-definition control holder 800 is installed at the output end of the cradle unit 600. The rack unit 600 and the network high-definition distribution control holder 800 are fixed through the connecting column 530, so that the rack unit 600 is fixed on the transport box 100. In the using process of the device, when the rack unit 600 is affected by external force, the connecting column 530 is driven to displace, and then the connecting column 530 transmits the external force to the return springs 540 distributed in the annular array. Utilize reset spring 540's elasticity to offset external force to make spliced pole 530 get back to the normal position, avoid network high definition to distribute accuse cloud platform 800 to influence the shooting effect because of displacement or vibrations, thereby improved network high definition and distributed the operating mass with the cloud platform 800.

The stand unit 600 includes a first telescopic bar 610, a stand mounting plate 620, and a rotation motor 630. For example, as shown in fig. 7, one end of the first telescopic rod 610 is hinged to the connecting column 530, and the other end of the first telescopic rod is fixedly connected to the bracket mounting plate 620, and the central axis of the bracket mounting plate 620 coincides with the central axis of the first telescopic rod 610. Support mounting panel 620 is close to a lateral wall edge department of first telescopic link 610 the axis of first telescopic link 610 is the center, and it has a plurality of groups second telescopic link 640 to be articulated in annular array, three groups are no less than to the quantity of second telescopic link 640. The rotary motor 630 is fixedly mounted on a side wall of the support mounting plate 620 far away from the first telescopic rod 610, and the network high-definition distribution control holder 800 is movably clamped at the output end of the rotary motor 630.

When installing network high definition cloth accuse cloud platform 800, at first take out first telescopic link 610 from support spacing groove 120 to rotate along its pin joint with spliced pole 530, make first telescopic link 610 keep away from the one end of pin joint perpendicularly upwards, and make the body of rod of first telescopic link 610 can the joint on fixture block 550. Then the first telescopic rods 610 are pulled apart to the corresponding length according to the required shooting height, and the plurality of groups of second telescopic rods 640 are all extended, so that the ends of the plurality of groups of second telescopic rods 640 far away from the support mounting plate 620 can be supported on the ground around the transport box 100 in an annular array. The network high-definition distribution control holder 800 is supported, and the whole shell of the bracket unit 600 is fixed on the transportation box 100 through the clamping relation between the first telescopic rod 610 and the connecting column 530. Then, the self weight of the transportation box 100 and the weight of the balance weight 700 are utilized to increase the stability of the support unit 600, so that the anti-interference capability of the network high-definition distribution control holder 800 during operation is improved.

The first telescopic rod 610 comprises an outer sleeve rod 611 and a lifting rod 613. For example, as shown in fig. 8, the outer rod 611 may be movably clamped to the holder latch 550. One end of the outer sleeve rod 611 is hinged to the connecting column 530, and the other end of the outer sleeve rod 611 is provided with a telescopic groove 612. One end of the lifting rod 613 is located in the telescopic groove 612, and the other end of the lifting rod 613 can movably penetrate through the outside of the telescopic groove 612 and is fixedly connected with the bracket mounting plate 620. An equipment socket 616 is fixedly installed on a side wall of one end of the lifting rod 613 close to the support mounting plate 620, and the equipment socket 616 can be electrically connected with the network high-definition distribution control holder 800. The one end that flexible groove 612 is close to spliced pole 530 is equipped with electric wire mounting groove 614, on the inner wall of electric wire mounting groove 614 both sides fixed mounting respectively have a set of drum dead lever 615, and is two sets of it is connected with drum body 617 to rotate between the drum dead lever 615, it has power cord module 650 to twine on the drum body 617, power cord module 650 one end with battery 300 electric connection, the power cord module 650 other end run through to in the lifter 613, and with equipment socket 616 electric connection.

The power line module 650 includes a power line body 652, and illustratively, as shown in fig. 9, an outer insulating sleeve 651 is sleeved outside the power line body 652, a clockwork spring 653 is fixedly installed in an inner wall of the outer insulating sleeve 651, and one end of the clockwork spring 653, which is far away from the device socket 616, is fixedly connected to the wire coil body 617.

Preferably, a conductive slip ring is fixedly installed on the central axis of the wire coil body 617, and the wire body 652 is electrically connected to the battery 300 through the conductive slip ring.

When the lifting rod 613 is pulled, the power line module 650 on the wire coil body 617 is pulled out. When the lifting rod 613 retracts, the power cord module 650 is rewound on the wire coil body 617 by the elastic force of the clockwork spring 653. The purpose of rolling the power line module 650 is realized, and the knotting of the power line module 650 is avoided.

When the network high-definition distribution and control holder 800 works, firstly, a plug of the network high-definition distribution and control holder 800 is plugged into the equipment socket 616, and then the power line module 650 which is arranged in the outer loop bar 611 and the lifting rod 613 is used for transmitting the electric energy of the storage battery 300 to the network high-definition distribution and control holder 800. The network high-definition distribution control holder 800 is not required to be additionally powered by an open wire, and the convenience of equipment use is improved.

The entire housing of the rack unit 600 is fixed to the transport box 100 by the snap-fit relationship between the first telescopic bar 610 and the connection post 530. Then, the self weight of the transportation box 100 and the weight of the balance weight 700 are utilized to increase the stability of the support unit 600, so that the anti-interference capability of the network high-definition distribution control holder 800 during operation is improved. When the rack unit 600 is affected by an external force, the connecting column 530 is driven to displace, and then the connecting column 530 transmits the external force to the return springs 540 distributed in the circular array. Utilize reset spring 540's elasticity to offset external force to make spliced pole 530 get back to the normal position, avoid network high definition to distribute accuse cloud platform 800 to influence the shooting effect because of displacement or vibrations, thereby improved network high definition and distributed the operating mass with the cloud platform 800. When the network high-definition distribution and control holder 800 works, firstly, a plug of the network high-definition distribution and control holder 800 is plugged into the equipment socket 616, and then the power line module 650 which is arranged in the outer loop bar 611 and the lifting rod 613 is used for transmitting the electric energy of the storage battery 300 to the network high-definition distribution and control holder 800. The network high-definition distribution control holder 800 is not required to be additionally powered by an open wire, and the convenience of equipment use is improved. When the transport box 100 is bumped during movement, a part of the impact force is first absorbed by the outer wall of the silicone block 410, and the remaining impact force is transmitted to one or several sets of the first buffer strips 430 corresponding to the bump point. The elastic force of the first buffer strip 430 is increased due to the characteristics of the corrugated structure of the first buffer strip 430. Therefore, when an impact force acts on the first buffer bar 430, it is substantially absorbed by the first buffer bar 430, and the remaining impact force is transferred to the other groups of the first buffer bars 430 through the second buffer bars 440. The shipping box 100 is prevented from receiving the impact force, and thus the shock-absorbing property of the shipping box 100 is improved.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. The utility model provides a remove intelligent security supervisory equipment which characterized in that: the device comprises a transport box (100), an upper cover (200), a bracket connecting unit (500), a bracket unit (600) and a network high-definition distribution control holder (800); the top of the transport box (100) is an open structure, and one side of the upper cover (200) is hinged at one side edge of the top of the transport box (100); the rack connection unit (500) is installed in a transport box (100), and the rack unit (600) includes a first telescopic rod (610) and a rack installation plate (620); one end of the first telescopic rod (610) is hinged to the support connecting unit (500), the other end of the first telescopic rod is fixedly connected with the support mounting plate (620), and the central axis of the support mounting plate (620) is superposed with the central axis of the first telescopic rod (610); the bracket mounting plate (620) is close to one side wall edge of the first telescopic rod (610), takes the central axis of the first telescopic rod (610) as the center, and is hinged with a plurality of groups of second telescopic rods (640) in an annular array, and the number of the second telescopic rods (640) is not less than three; the network high-definition distribution and control cloud deck (800) is movably arranged on the support mounting plate (620); an industrial gateway is installed in the transportation box (100), and the industrial gateway is electrically connected with the network high-definition distribution control holder (800).

2. The mobile intelligent security surveillance device of claim 1, wherein: a storage battery (300) is arranged in the transportation box (100), and the storage battery (300) is electrically connected with the support unit (600) and the industrial gateway respectively.

3. The mobile intelligent security surveillance device of claim 1, wherein: a foam block (110) is fixedly installed in the transportation box (100), a support limiting groove (120) is formed in the top of the foam block (110), and one end, close to the support unit (600), of the support limiting groove (120) is of an open structure; the bracket unit (600) can be movably inserted into the bracket limiting groove (120); an equipment limiting groove (130) is formed in one side of the support limiting groove (120), and the network high-definition distribution control holder (800) can be movably inserted into the equipment limiting groove (130).

4. The mobile intelligent security surveillance device of claim 1, wherein: the monitoring device further comprises two groups of shock absorption units (400), wherein each shock absorption unit (400) comprises a silica gel block (410); the two groups of silica gel blocks (410) are respectively and fixedly installed at the corners of the bottoms of the outer walls at the two sides of the transportation box (100), and a damping inner cavity (420) is formed in each silica gel block (410); a plurality of groups of first buffer strips (430) are distributed in the shock absorption inner cavity (420) at equal intervals, two ends of each first buffer strip (430) are respectively installed on two parallel side walls of the shock absorption inner cavity (420) and the transportation box (100), and the first buffer strips (430) are of a corrugated structure.

5. The mobile intelligent security surveillance device of claim 1, wherein: the bracket connection unit (500) includes a connection column base (510) and a connection column (530); the connecting column base (510) is arranged in the transport box (100); an annular groove (520) is formed in the top of the connecting column base (510), the connecting column (530) is installed in the annular groove (520), and the central axis of the connecting column (530) is overlapped with the central axis of the annular groove (520); a plurality of groups of reset springs (540) are distributed on the outer wall of the connecting column (530) in an annular array, and the other ends of the reset springs (540) are respectively installed on the peripheral inner wall of the annular groove (520).

6. The mobile intelligent security surveillance device of claim 5, wherein: one end of the bracket unit (600) is hinged to the connecting column (530), a bracket clamping block (550) is fixedly mounted on the outer wall of one side, close to the bracket limiting groove (120), of the connecting column (530), and the bracket clamping block (550) is located right above the joint of the bracket unit (600) and the connecting column (530); the output end of the bracket unit (600) is movably clamped on the bracket clamping block (550).

7. The mobile intelligent security surveillance device of claim 6, wherein: the stand unit (600) further comprises a rotary motor (630); the rotary motor (630) is fixedly mounted on a side wall of the support mounting plate (620) far away from the first telescopic rod (610), and the network high-definition distribution control holder (800) is movably connected to the output end of the rotary motor (630).

8. The mobile intelligent security surveillance device of claim 7, wherein: the first telescopic rod (610) comprises an outer sleeved rod (611); the outer loop bar (611) is movably clamped on the bracket clamping block (550); one end of the outer sleeve rod (611) is hinged to the connecting column (530), and the other end of the outer sleeve rod (611) is provided with a telescopic groove (612).

9. The mobile intelligent security surveillance device of claim 8, wherein: the first telescopic rod (610) further comprises a lifting rod (613); one end of the lifting rod (613) is positioned in the telescopic groove (612), and the other end of the lifting rod (613) can movably penetrate through the outside of the telescopic groove (612) and is fixedly connected with the support mounting plate (620).

10. The mobile intelligent security surveillance device of claim 2 or 9, characterized in that: fixed mounting has equipment socket (616) on lifter (613) is close to the one end lateral wall of support mounting panel (620), equipment socket (616) can with network high definition cloth accuse cloud platform (800) electric connection.