CN112483858A

CN112483858A - Modern logistics facility engineering construction supervision method

Info

Publication number: CN112483858A
Application number: CN202011239601.XA
Authority: CN
Inventors: 周明权
Original assignee: Zhejiang Hongtai Engineering Project Management Co ltd
Current assignee: Zhejiang Hongtai Engineering Project Management Co ltd
Priority date: 2020-11-09
Filing date: 2020-11-09
Publication date: 2021-03-12
Anticipated expiration: 2040-11-09
Also published as: CN112483858B

Abstract

The invention discloses a modern logistics facility engineering construction supervision method, and aims to provide a modern logistics facility engineering construction supervision method with a good monitoring effect. It comprises the following steps: the method comprises the following steps: mounting the mounting plate on a wall surface; step two: mounting a rotating assembly on the mounting plate; step three: a fixer is arranged on the rotating component; step four: a camera is arranged on the fixer; step five: the rotating assembly and the fixer are matched to drive the camera to rotate for monitoring. The invention has the beneficial effects that: the monitoring effect is good, and the mounting panel is fixed firm, and the motor provides the power supply, and firm in connection rotates effectually, rotates the focus steady, the elasticity of control hasp that can be better, and the protection probe makes it not be infected with the dust, and the guide effect is good, and is spacing effectual.

Description

Modern logistics facility engineering construction supervision method

Technical Field

The invention relates to the technical field of engineering construction, in particular to a modern logistics facility engineering construction supervision method.

Background

The modern logistics facility engineering construction supervision method comprises a production management system, a transportation management system, a construction management system, an operation management system, a monitoring system, a construction management system and a recycling system, wherein all the systems are connected in pairs, and the systems are connected in data, the modern logistics facility engineering construction supervision method refers to the information and the process in the whole life cycle of the construction products participating in public infrastructure, specifically the information and the process in the whole life cycle of the requirement, planning, design, production, distribution, operation, use, maintenance and recycling disposal of the construction products, is a technology and a manufacturing concept, supports advanced design and manufacturing technologies such as parallel design, agile manufacturing, collaborative design and manufacturing, networked manufacturing and the like, but the existing modern logistics facility engineering construction supervision method is still imperfect, in addition, a monitoring system in a periodic system of the modern logistics facility engineering construction supervision method has a relatively large leak, and the most prominent monitoring system is a camera monitoring device in the monitoring system.

Disclosure of Invention

The invention provides a modern logistics facility engineering construction supervision method with good monitoring effect, aiming at overcoming the defect of poor monitoring effect in the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme:

a modern logistics facility engineering construction supervision method is characterized by comprising the following steps:

the method comprises the following steps: mounting the mounting plate on a wall surface;

step two: mounting a rotating assembly on the mounting plate;

step three: a fixer is arranged on the rotating component;

step four: a camera is arranged on the fixer;

step five: the rotating assembly and the fixer are matched to drive the camera to rotate for monitoring.

This monitoring device of modern logistics facility engineering construction supervision method mainly includes the mounting panel, the runner assembly, fixer and camera, at first fix whole device at the wall that can monitor required monitoring area through the mounting panel, then the camera is through connecting on the fixer, drive the camera by the fixer and rotate from top to bottom, the runner assembly is connected to the fixer, the runner assembly rotates about again, thereby monitoring device can carry out the control of all directions about from top to bottom to the region that needs the control, the camera uploads monitoring data to monitoring device, the mesh that monitoring effect is good has been reached.

Preferably, the bottom end of the rotating assembly is connected with the mounting plate, the top end of the rotating assembly is connected with the bottom end of the fixer, the top end of the fixer is connected with the camera, the fixer comprises a fixer body and a first rotating shaft, a second through hole is formed in the side end of the fixer body, the first rotating shaft penetrates through the second through hole and is connected with the fixer body in a rotating mode, an arc-shaped surface is arranged at the top end of the fixer body, a connecting column is arranged at the bottom end of the fixer body and is connected with the rotating assembly, a third through hole is formed in the middle of the first rotating shaft, the camera is connected with the first rotating shaft through the third through hole, a plurality of first through holes are formed in the mounting plate, a first fixing column matched with the first through holes is installed on the first. The design of the mounting plate and the first fixing column can firmly fix the monitoring device on the wall surface which can monitor the required monitoring area, and basic conditions are provided for the operation of the monitoring device.

Preferably, a first gear box is arranged on two sides of the device body, a first box hole is formed in the first gear box, the first rotating shaft sequentially penetrates through a second through hole and the first box hole, the first rotating shaft is connected with the first gear box through the first box hole, a first motor is arranged in the first gear box, a second gear box is arranged at the joint of the connecting column and the rotating assembly, the top end of the second gear box is connected with the connecting column, the bottom end of the second gear box is connected with the rotating assembly, and a second motor is arranged in the second gear box. The first motor and the second motor respectively provide power sources for the first gear box and the second gear box, and gears in the first gear box rotate to drive the first rotating shaft to rotate up and down.

Preferably, the rotating assembly comprises a support frame and a rotating joint, the bottom end of the support frame is welded with the mounting plate, a second fixing column is welded at the top end of the support frame, a lock catch matched with the second fixing column is arranged on the second fixing column, the bottom end of the lock catch is connected with the second fixing column, the top end of the lock catch is connected with the bottom end of the rotating joint, and the top end of the rotating joint is connected with the second gear box. The design of the lock catch enables the connection between the rotating joint and the supporting frame to be firmer.

Preferably, the rotary joint comprises an upper portion and a lower portion, a second rotating shaft penetrating through the upper portion is arranged in the upper portion, the upper portion is arranged between two ends of the second rotating shaft, a second box hole is formed in the top end and the bottom end of the second gear box, the top end of the second rotating shaft penetrates through the second box hole and is connected with the fixer, the bottom end of the second rotating shaft is connected with the top end of the lower portion, and the bottom end of the lower portion is fixedly connected with the lock catch. The second rotating shaft and the second box hole are designed, so that gears in the second gear box drive the second rotating shaft to rotate left and right to drive the fixator to rotate left and right, and then the camera is further driven to rotate left and right.

Preferably, a rotating hole is formed in the lower portion, the top end of the rotating hole is in contact with the bottom end of the upper portion, a rotating cavity is formed in the bottom end of the rotating hole and is communicated with the rotating hole, the second rotating shaft is rotatably connected with the rotating hole and the rotating cavity, and the cross section of the bottom end of the second rotating shaft is in a cross shape. The bottom end of the second rotating shaft is designed in a cross shape, so that the center of gravity of the bottom end of the second rotating shaft is more stable when the second rotating shaft rotates, and the left and right rotation of the camera is more easily controlled.

Preferably, a pair of ears is mounted on the side wall of the lock catch, and the two ears are distributed in bilateral symmetry. The design of the ears enables the lock catch to be stressed more easily so as to rotate loosely or tightly, and the tightness of the lock catch can be controlled better.

Preferably, the camera comprises a dust cover, a probe and a third fixing column, the dust cover is connected with the probe, the top end of the third fixing column is connected with the probe, and the bottom end of the third fixing column is connected with the first rotating shaft through a third through hole. The design of dust cover can protect the probe to make it be infected with the dust and avoid influencing the monitoring effect.

Preferably, the bottom of the upper portion is provided with a plurality of fourth fixing columns, the four adjacent fixing columns are distributed equidistantly, the four fixing columns are arranged on the outer side of the rotating hole, the top of the lower portion is provided with a plurality of limiting grooves matched with the four fixing columns, the bottom of the four fixing columns is connected with the limiting grooves in a clamped mode, the top of the four fixing columns is connected with the bottom of the upper portion, the bottom of the four fixing columns is provided with a first limiting piece, the bottom of the four fixing columns is spherical, and the bottom of the first limiting piece is arc-shaped. Spacing piece one is the silica gel material, can warp, can be firm with the spacing groove joint after four entering spacing grooves of fixed column, avoid droing, and the spherical design in four bottoms of fixed column and the curved design in spacing piece bottom provide fine guide effect for this fixed column four for fixed column four is easier quicker to be connected with the spacing groove.

Preferably, a plurality of second limiting pieces are arranged in the rotating cavity, the diameter of the rotating cavity is larger than that of the rotating hole, the upper surfaces of the second limiting pieces form an angle a with the horizontal line, the angle a is an acute angle, and the lower surfaces of the second limiting pieces are parallel to the horizontal line. The second limiting plate is made of silica gel and can deform, the second limiting plate begins to deform when the second rotating shaft contacts the second limiting plate, the second limiting plate resets when the second rotating shaft passes through the second limiting plate, the diameter of the rotating cavity is larger than that of the rotating hole, so that the second limiting plate can be retracted to ensure that the second rotating shaft can smoothly pass through the second limiting plate when the second limiting plate contracts, and the second rotating shaft is easier to pass through the second limiting plate due to the design of the angle a and is not easy to fall off after the second limiting plate resets.

The invention has the beneficial effects that: the monitoring effect is good, and the mounting panel is fixed firm, and the motor provides the power supply, and firm in connection rotates effectually, rotates the focus steady, the elasticity of control hasp that can be better, and the protection probe makes it not be infected with the dust, and the guide effect is good, and is spacing effectual.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an exploded view of the anchor;

FIG. 3 is a schematic structural diagram of a camera;

FIG. 4 is a schematic view of the construction of the rotary joint;

FIG. 5 is an enlarged view of A of FIG. 4;

FIG. 6 is a top view of the lower portion;

fig. 7 is a sectional view taken along line B-B of fig. 6.

In the figure: 1. the mounting plate, 2, the fixer, 3, the camera, 4, the body, 5, the rotating shaft I, 6, the through hole II, 7, the connecting column, 8, the through hole III, 9, the through hole I, 10, the fixing column I, 11, the gear box I, 12, the box hole I, 13, the gear box II, 14, the supporting frame, 15, the rotating joint, 16, the fixing column II, 17, the lock catch, 18, the upper part, 19, the lower part, 20, the rotating shaft II, 21, the box hole II, 22, the rotating hole, 23, the rotating cavity, 24, the ear, 25, the dust cover, 26, the probe, 27, the fixing column III, 28, the fixing column IV, 29, the limiting groove, 30, the limiting sheet I, 31 and the limiting sheet II.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

In the embodiment shown in fig. 1 and 2, a modern logistics facility engineering construction supervision method comprises the following steps:

the method comprises the following steps: mounting the mounting plate 1 on a wall surface;

step two: a rotating component is arranged on the mounting plate 1;

step three: a fixer 2 is arranged on the rotating component;

step four: a camera 3 is arranged on the fixer 2;

step five: the rotating assembly and the fixer 2 are matched to drive the camera 3 to rotate for monitoring.

Wherein: the bottom end of the rotating assembly is connected with the mounting plate 1, the top end of the rotating assembly is connected with the bottom end of the fixer 2, the top end of the fixer 2 is connected with the camera 3, the fixer 2 comprises a body 4 and a first rotating shaft 5, the side end of the body 4 is provided with a second through hole 6, the first rotating shaft 5 penetrates through the second through hole 6 to be rotatably connected with the body 4, the top end of the body 4 is provided with an arc surface, the bottom end of the body 4 is provided with a connecting post 7, the connecting post 7 is connected with the rotating assembly, the middle of the first rotating shaft 5 is provided with a third through hole 8, the camera 3 is connected with the first rotating shaft 5 through the third through hole 8, the mounting plate 1 is provided with a plurality of first through holes 9, the first fixing posts 10 matched with the first through holes 9 are mounted on the first through holes 9, the first through holes 9 are in threaded connection with the first fixing posts 10, the two sides of the body 4 are, the rotating shaft I5 is connected with the gear box I11 through a box hole I12, a motor I is arranged in the gear box I11, a gear box II 13 is arranged at the joint of the connecting column 7 and the rotating assembly, the top end of the gear box II 13 is connected with the connecting column 7, the bottom end of the gear box II 13 is connected with the rotating assembly, a motor II is arranged in the gear box II 13, the rotating assembly comprises a supporting frame 14 and a rotating joint 15, the bottom end of the supporting frame 14 is welded with the mounting plate 1, a fixing column II 16 is welded at the top end of the supporting frame 14, a lock catch 17 matched with the fixing column II 16 is arranged on the fixing column II 16, the bottom end of the lock catch 17 is connected with the bottom end of the rotating joint 15, the top end of the rotating joint 15 is connected with the gear box II 13, as shown in figure 4, the rotating joint 15 comprises an upper portion 18 and a lower portion, the top end and the bottom end of the second gear box 13 are both provided with a second box hole 21, the top end of the second rotating shaft 20 penetrates through the second box hole 21 to be connected with the fixer 2, the bottom end of the second rotating shaft 20 is connected with the top end of the lower portion 19, and the bottom end of the lower portion 19 is fixedly connected with the lock catch 17.

As shown in fig. 6 and 7, a rotation hole 22 is formed inside the lower portion 19, the top end of the rotation hole 22 is in contact with the bottom end of the upper portion 18, a rotation cavity 23 is formed at the bottom end of the rotation hole 22, the rotation cavity 23 is communicated with the rotation hole 22, the second rotation shaft 20 is in rotational connection with the rotation hole 22 and the rotation cavity 23, the cross-sectional shape of the bottom end of the second rotation shaft 20 is cross-shaped, as shown in fig. 1, a pair of ears 24 are mounted on the side wall of the lock catch 17, the two ears 24 are symmetrically distributed in the left and right direction, as shown in fig. 3, the camera 3 comprises a dust cover 25, a probe 26 and a fixed column three 27, the dust cover 25 is connected with the probe 26, the top end of the fixed column three 27 is connected with the probe 26, the bottom end of the fixed column three 27 is connected with the first rotation shaft 5 through a through hole three 8, as shown in fig. 4 and 5, a plurality of fixed, the top end of the lower portion 19 is provided with a plurality of limiting grooves 29 matched with the four fixing columns 28, the bottom ends of the four fixing columns 28 are clamped with the limiting grooves 29, the top ends of the four fixing columns 28 are connected with the bottom end of the upper portion 18, the bottom ends of the four fixing columns 28 are provided with limiting pieces 30, the bottom ends of the four fixing columns 28 are spherical, the bottom ends of the limiting pieces 30 are arc-shaped, as shown in fig. 7, a plurality of limiting pieces two 31 are arranged in the rotating cavity 23, the diameter of the rotating cavity 23 is larger than that of the rotating hole 22, the upper surfaces of the limiting pieces two 31 are at an angle a with the horizontal line, the angle a is an acute angle, and the lower surfaces of.

The specific operation is as follows: firstly, the whole device is fixed on a wall surface which can monitor a required monitoring area by a mounting plate 1, then a camera 3 is connected with a fixer 2 through a first rotating shaft 5 arranged on a fixer body 4, then a first gear box 11 on two sides of the fixer 2 drives a gear in the first gear box 11 to rotate up and down under the power action of a first motor, the gear drives a first rotating shaft 5 to rotate up and down so as to drive the camera 3 to rotate up and down, a second gear box 13 connected with the bottom end of the fixer body 4 drives a gear in the second gear box 13 to rotate left and right under the power action of a second motor, the gear drives a second rotating shaft 20 to rotate left and right, the second rotating shaft 20 drives the camera 3 to rotate left and right by driving the body 4 of the fixer 2 to rotate left and right, a rotating joint 15 comprises an upper part 18 and a lower part 19, the second rotating shaft 20 penetrates through the upper part 18, the cross-section shape of the second rotating shaft 20 on the outer side of the second rotating shaft 20, therefore, the left and right rotation of the camera 3 is controlled more easily, the second fixed column 16 is arranged at the bottom end of the upper part 18, the limiting groove 29 is arranged at the top end of the lower part 19, the fourth fixed column 28 is clamped with the limiting groove 29 to enable the bottom end of the rotating ring to be fixedly connected with the top end of the lower part 19, the second rotating shaft 20 is respectively and rotatably connected with the fixer 2, the second gear box 13, the upper part 18, the rotating hole 22 and the rotating cavity 23, the second limiting sheet 31 in the rotating cavity 23 is made of silica gel and can deform, the second limiting sheet 31 starts to deform when the second rotating shaft 20 contacts the second limiting sheet 31, the second limiting sheet 31 resets when the second rotating shaft 20 passes through the second limiting sheet 31, the diameter of the rotating cavity 23 is larger than that of the rotating hole 22, so that the second limiting sheet 31 has a certain shrinkage space when the second limiting sheet 31 shrinks, the second rotating shaft 20 can smoothly pass through the second limiting sheet 31, the design of the angle a enables the second rotating shaft, two 20 of pivot can not break away from under general dynamics and rotate chamber 23, if the dynamics is strengthened, two 20 of pivot alright dismantle in order to break away from rotating chamber 23, spacing piece 30 also is the silica gel material, can warp, can get into spacing groove 29 after the fixed column four 28 firm with spacing groove 29 joint, avoid droing, the spherical design in fixed column four 28 bottom and the curved design in spacing piece one 30 bottom provide fine guide effect for this fixed column four 28, lower part 19 has guaranteed with hasp 17 fixed connection that lower part 19 can be with backup pad firm in connection, the good mesh of monitoring effect has been reached.

Claims

1. A modern logistics facility engineering construction supervision method is characterized by comprising the following steps:

the method comprises the following steps: mounting the mounting plate (1) on a wall surface;

step two: a rotating component is arranged on the mounting plate (1);

step three: a fixer (2) is arranged on the rotating component;

step four: a camera (3) is arranged on the fixer (2);

step five: the rotating assembly is matched with the fixer (2) to drive the camera (3) to rotate for monitoring.

2. The modern logistics facility engineering construction supervision method according to claim 1, wherein the bottom end of the rotating assembly is connected with a mounting plate (1), the top end of the rotating assembly is connected with the bottom end of a fixer (2), the top end of the fixer (2) is connected with a camera (3), the fixer (2) comprises a body (4) and a first rotating shaft (5), a second through hole (6) is formed in the side end of the body (4), the first rotating shaft (5) penetrates through the second through hole (6) to be rotatably connected with the body (4), an arc-shaped surface is formed in the top end of the body (4), a connecting column (7) is formed in the bottom end of the body (4), the connecting column (7) is connected with the rotating assembly, a third through hole (8) is formed in the middle of the first rotating shaft (5), and the camera (3) is connected with the first rotating shaft (5) through the third through hole (8), the mounting plate is characterized in that a plurality of first through holes (9) are formed in the mounting plate (1), first fixing columns (10) matched with the first through holes (9) are installed on the first through holes (9), and the first through holes (9) are in threaded connection with the first fixing columns (10).

3. The modern logistics facility engineering construction supervision method according to claim 2, wherein a first gear box (11) is arranged on each of two sides of the device body (4), a first box hole (12) is formed in each gear box (11), the first rotating shaft (5) sequentially penetrates through a second through hole (6) and the first box hole (12), the first rotating shaft (5) is connected with the first gear box (11) through the first box hole (12), a first motor is arranged in each gear box (11), a second gear box (13) is arranged at the joint of the connecting column (7) and the rotating assembly, the top end of the second gear box (13) is connected with the connecting column (7), the bottom end of the second gear box (13) is connected with the rotating assembly, and a second motor is arranged in each second gear box (13).

4. The modern logistics facility engineering construction supervision method according to claim 3, wherein the rotating assembly comprises a support frame (14) and a rotating joint (15), the bottom end of the support frame (14) is welded with the mounting plate (1), a second fixing column (16) is welded at the top end of the support frame (14), a lock catch (17) matched with the second fixing column (16) is arranged on the second fixing column (16), the bottom end of the lock catch (17) is connected with the second fixing column (16), the top end of the lock catch (17) is connected with the bottom end of the rotating joint (15), and the top end of the rotating joint (15) is connected with the second gear box (13).

5. The modern logistics facility engineering construction supervision method according to claim 4, wherein the rotary joint (15) comprises an upper part (18) and a lower part (19), a second rotating shaft (20) penetrating through the upper part (18) is arranged in the upper part (18), the upper part (18) is arranged between two ends of the second rotating shaft (20), a second box hole (21) is formed in each of the top end and the bottom end of the second gear box (13), the top end of the second rotating shaft (20) penetrates through the second box hole (21) to be connected with the fixer (2), the bottom end of the second rotating shaft (20) is connected with the top end of the lower part (19), and the bottom end of the lower part (19) is fixedly connected with the lock catch (17).

6. The modern logistics facility engineering construction supervision method according to claim 5, wherein a rotating hole (22) is formed in the lower portion (19), the top end of the rotating hole (22) is in contact with the bottom end of the upper portion (18), a rotating cavity (23) is formed in the bottom end of the rotating hole (22), the rotating cavity (23) is communicated with the rotating hole (22), the second rotating shaft (20) is rotatably connected with the rotating hole (22) and the rotating cavity (23), and the cross section of the bottom end of the second rotating shaft (20) is in a cross shape.

7. The modern logistics facility engineering construction supervision method according to claim 4, wherein a pair of ears (24) is installed on the side wall of the lock catch (17), and the two ears (24) are distributed symmetrically left and right.

8. The modern logistics facility engineering construction supervision method according to claim 1, 2 or 3, wherein the camera (3) comprises a dustproof cover (25), a probe (26) and a third fixed column (27), the dustproof cover (25) is connected with the probe (26), the top end of the third fixed column (27) is connected with the probe (26), and the bottom end of the third fixed column (27) is connected with the first rotating shaft (5) through a third through hole (8).

9. The modern logistics facility engineering construction supervision method according to claim 5, wherein the bottom end of the upper portion (18) is provided with a plurality of fixing column four (28), two adjacent fixing column four (28) are distributed at equal intervals, the fixing column four (28) is arranged on the outer side of the rotating hole (22), the top end of the lower portion (19) is provided with a plurality of limiting grooves (29) matched with the fixing column four (28), the bottom ends of the fixing column four (28) are clamped with the limiting grooves (29), the top ends of the fixing column four (28) are connected with the bottom end of the upper portion (18), the bottom end of the fixing column four (28) is provided with a limiting piece one (30), the bottom end of the fixing column four (28) is spherical, and the bottom end of the limiting piece one (30) is arc-shaped.

10. The modern logistics facility engineering construction supervision method according to claim 6, wherein a plurality of second limiting pieces (31) are arranged in the rotating cavity (23), the diameter of the rotating cavity (23) is larger than that of the rotating hole (22), the upper surfaces of the second limiting pieces (31) form an angle a with a horizontal line, the angle a is an acute angle, and the lower surfaces of the second limiting pieces (31) are parallel to the horizontal line.