CN211317379U - Historical protection building optical fiber monitoring device - Google Patents

Abstract

The utility model discloses a historical protection building optical fiber monitoring device, which belongs to the technical field of optical fiber monitoring devices and comprises a vertical rod, wherein a monitoring camera is arranged at one side of the vertical rod close to the upper part, a control box is arranged at one side of the middle position of the vertical rod, the monitoring camera and the vertical rod as well as the control box and the vertical rod are fixed through mounting seats, an optical fiber sensor is fixed at one side of the control box far away from the mounting seats close to the lower part, and a supporting table is fixed on the vertical rod and below the control box; the utility model discloses a set up sliding tray, sliding block, slip ring, fixed block, roating seat, revolving stage, swivelling chute and fixed slot, multiple structure mutually supports, can realize surveillance camera head, optical fiber sensor and control box angularly adjustable function, and then can adjust under the condition that the installation angle has the deviation to need not the staff and install again, accelerate the installation rate of device.

Description

Historical protection building optical fiber monitoring device

Technical Field

The utility model belongs to the technical field of the optical fiber monitoring device, concretely relates to historical protection building optical fiber monitoring device.

Background

Historical buildings are carriers of cultural spirit, rich cultural connotations can be understood through the historical buildings, and the historical buildings are 'symbols of historical memory' and 'chains of urban cultural development' in a certain sense, so protection is needed.

The prior art has the following problems: the installation structure of the existing historical protection building optical fiber monitoring device is fixed and unadjustable, and the installation structure needs to be installed again by workers under the condition that the installation angle is deviated, so that the installation speed of the device is reduced.

SUMMERY OF THE UTILITY MODEL

To solve the problems set forth in the background art described above. The utility model provides a historical protection building optical fiber monitoring device has and to adjust under the condition that the installation angle has the deviation to need not the staff and install again, accelerate device installation rate and accelerate the characteristics of radiating rate.

In order to achieve the above object, the utility model provides a following technical scheme: a historical protection building optical fiber monitoring device comprises a vertical rod, wherein a monitoring camera is installed on one side of the vertical rod close to the upper part, a control box is installed on one side of the middle position of the vertical rod, the monitoring camera and the vertical rod and the control box and the vertical rod are fixed through mounting seats, an optical fiber sensor is fixed on one side of the control box far away from the mounting seats close to the lower part, a supporting table is fixed on the vertical rod and below the control box, a mounting groove is formed in the supporting table and in the position of one control box, a plurality of through holes are formed below the mounting groove, a heat dissipation assembly is fixed below the supporting table, a sliding groove is formed below the vertical rod, a sliding block is connected inside the sliding groove, a sliding ring is fixed at one end of the sliding block far away from the sliding groove, and fixed blocks are connected to two sides below the sliding ring, the roating seat is installed to the below of pole setting, the outside of roating seat is connected with the revolving stage, the swivelling chute has been seted up to the position that just corresponds the roating seat on the revolving stage, the position circumference equipartition that just corresponds the fixed block on the revolving stage has a plurality of fixed slot, two bracing pieces are installed to the below symmetry of revolving stage, two the below of bracing piece is fixed with the mount table.

Preferably, radiator unit includes fixing bolt, gear motor, heat dissipation casing, heat dissipation post, blade, rotation axis and louvre, wherein, a plurality of louvre has been seted up to gear motor's lower extreme, gear motor's inside is connected with the rotation axis by the lower extreme, a plurality of blade is installed in the outside of rotation axis, the input axle head of rotation axis is connected with the heat dissipation casing, a plurality of heat dissipation post is installed to the top of rotation axis, gear motor leans on upper end outward flange circumference equipartition to have fixing bolt.

Preferably, the mounting seat and the vertical rod are fixed in a welding mode.

Preferably, the rotary groove is of a smooth structure.

Preferably, the last one end that just corresponds the rotation axis and keeps away from the heat dissipation casing of gear motor has seted up the mounting hole, the last one end that just corresponds the rotation axis and is close to the heat dissipation casing of gear motor has seted up the perforation, all rotate through the bearing between rotation axis and mounting hole and rotation axis and the perforation and be connected.

Preferably, one end of each of the heat dissipation columns, which is far away from the rotating shaft, penetrates through the corresponding through hole to abut against the lower side wall of the control box.

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

1. the utility model discloses a set up sliding tray, sliding block, slip ring, fixed block, roating seat, revolving stage, swivelling chute and fixed slot, multiple structure mutually supports, can realize surveillance camera head, optical fiber sensor and control box angularly adjustable function, and then can adjust under the condition that the installation angle has the deviation to need not the staff and install again, accelerate the installation rate of device.

2. The utility model discloses a brace table is through setting up the through-hole, radiator unit is through setting up the heat dissipation casing, fixing bolt, heat dissipation post and louvre, multiple structure mutually supports, can give off the leading-in heat dissipation casing of heat that the control box did not in time give off in the external environment, and then accelerate the radiating rate of control box, thereby build good operational environment for the structure in the control box, radiator unit is through setting up gear motor, rotation axis and blade simultaneously, multiple structure mutually supports, can accelerate thermal quick transmission and dispersion.

Drawings

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

FIG. 2 is a schematic side-sectional view of the present invention;

FIG. 3 is an enlarged schematic view of FIG. 2A according to the present invention;

in the figure: 1. a surveillance camera; 2. an optical fiber sensor; 3. a heat dissipating component; 31. fixing the bolt; 32. a reduction motor; 33. a heat dissipating housing; 34. a heat-dissipating column; 35. a blade; 36. a rotating shaft; 37. heat dissipation holes; 4. an installation table; 5. a support bar; 6. a rotating table; 7. a slip ring; 8. a support table; 9. a control box; 10. a mounting seat; 11. erecting a rod; 12. a slider; 13. mounting grooves; 14. a through hole; 15. fixing grooves; 16. a rotating base; 17. a rotating tank; 18. a fixed block; 19. a sliding groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides the following technical solutions: a historical protection building optical fiber monitoring device comprises an upright rod 11, a monitoring camera 1 is installed on one side of the upright rod 11 close to the upper side, a control box 9 is installed on one side of the middle position of the upright rod 11, the monitoring camera 1 and the upright rod 11 as well as the control box 9 and the upright rod 11 are fixed through an installation seat 10, in order to enable the monitoring camera 1 and the control box 9 to be connected with the upright rod 11 more firmly, in the embodiment, preferably, an optical fiber sensor 2 is fixed on one side of the control box 9 far away from the installation seat 10 close to the lower side through a welding mode between the installation seat 10 and the upright rod 11, a support table 8 is fixed on the upright rod 11 and located below the control box 9, an installation groove 13 is formed in the support table 8 and used for installing one control box 9, a plurality of through holes 14 are formed below the installation groove 13, a heat dissipation component 3 is fixed below the support table 8, and a sliding groove 19 is formed below the upright rod 11, sliding tray 19's internally connected has sliding block 12, sliding block 12 is kept away from sliding tray 19's one end and is fixed with sliding ring 7, sliding ring 7's below both sides all are connected with fixed block 18, roating seat 16 is installed to the below of pole setting 11, roating seat 16's the outside is connected with revolving stage 6, and roating seat 17 has been seted up to the position that just corresponds roating seat 16 on the revolving stage 6, for the convenience of roating seat 16 rotates, in this embodiment, it is preferred, roating groove 17 sets up for smooth structure, the position circumference equipartition that just corresponds fixed block 18 on the revolving stage 6 has a plurality of fixed slot 15, two bracing pieces 5 are installed to revolving stage 6's below symmetry, the below of two bracing pieces 5 is.

In order to have a good heat dissipation effect, in this embodiment, preferably, the heat dissipation assembly 3 includes a fixing bolt 31, a speed reduction motor 32, a heat dissipation housing 33, heat dissipation columns 34, blades 35, a rotation shaft 36 and heat dissipation holes 37, wherein a plurality of heat dissipation holes 37 are formed at a lower end of the speed reduction motor 32, the rotation shaft 36 is connected to an inner portion of the speed reduction motor 32 near the lower end, a plurality of blades 35 are installed at an outer side of the rotation shaft 36, the heat dissipation housing 33 is connected to an input shaft end of the rotation shaft 36, in order to facilitate rotation of the rotation shaft 36, in this embodiment, preferably, a mounting hole is formed at one end of the speed reduction motor 32, which is far from the heat dissipation housing 33 and corresponds to the rotation shaft 36, a through hole is formed at one end of the speed reduction motor 32, which is close to the heat dissipation housing 33 and corresponds to the rotation shaft, fixing bolts 31 are evenly distributed on the circumference of the outer edge close to the upper end of the speed reducing motor 32.

In order to facilitate the heat dissipation columns 34 to guide the heat of the control box 9 into the heat dissipation housing 33, in the present embodiment, it is preferable that one ends of the plurality of heat dissipation columns 34, which are far away from the rotating shaft 36, pass through the corresponding through holes 14 to abut against the lower side wall of the control box 9.

The utility model discloses a theory of operation and use flow: installation work: installing the installation table 4 at a used position, if the installation angle has no deviation, using an external power supply starting device, if the installation angle has deviation, pulling the sliding ring 7 upwards, sliding blocks 12 on the inner side of the sliding ring 7 upwards slide in sliding grooves 19 of the upright rods 11 and drive the sliding ring 7 to move upwards until the fixed blocks 18 are separated from the inside of the fixed grooves 15 and stop, then rotating the upright rods 11, rotating the rotary seat 16 in a rotary groove 17 of the rotary table 6, stopping rotating the rotary seat 16 when the installation angle has no deviation, loosening the sliding ring 7, moving the sliding ring 7 downwards under the action of self gravity until the fixed blocks 18 are completely clamped in the inside of the fixed grooves 15 and stop, realizing the position fixation of the upright rods 11, finishing the angle adjustment, and using the external power supply starting device; monitoring work: the monitoring camera 1 and the optical fiber sensor 2 monitor the historical protection building in real time, the monitoring camera 1 transmits the shot image to a central processing unit (not shown in the figure) of the control box 9, the optical fiber sensor 2 converts the sensed physical, chemical and biological information into a special electronic component of electrical information and transmits the special electronic component to the central processing unit of the control box 9, and the central processing unit processes and analyzes the received information and displays the analysis result on a display screen (not shown in the figure), so that the structural resistance of the historical protection building structure is reduced due to fatigue effect and material aging, and the historical protection building structure is reminded to prevent people from threatening life safety; heat dissipation work: in the monitoring operation, the heat dissipation column 34 guides the heat that is not timely dissipated by the control box 9 in the external environment into the heat dissipation housing 33 and discharges the heat from the heat dissipation hole 37, and meanwhile, the speed reduction motor 32 drives the rotation shaft 36 to rotate, and the rotation shaft 36 drives the blades 35 to rotate, so that the air flow speed is increased, and the heat is dissipated out of the heat dissipation housing 33 more quickly.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a history protection building optic fibre monitoring devices, includes pole setting (11), its characterized in that: the monitoring camera (1) is installed on one side of the upright rod (11) close to the upper part, the control box (9) is installed on one side of the middle position of the upright rod (11), the monitoring camera (1), the upright rod (11) and the control box (9) and the upright rod (11) are fixed through the mounting seat (10), the optical fiber sensor (2) is fixed on one side of the control box (9) far away from the mounting seat (10) close to the lower part, the supporting table (8) is fixed on the upright rod (11) and below the control box (9), the supporting table (8) is provided with a mounting groove (13) on the position of one control box (9), a plurality of through holes (14) are formed below the mounting groove (13), the heat dissipation component (3) is fixed below the supporting table (8), the sliding groove (19) is formed on the upright rod (11) close to the lower part, and the sliding block (12) is connected inside the sliding groove (19), sliding block (12) keep away from the one end of sliding tray (19) and be fixed with slip ring (7), the below both sides of slip ring (7) all are connected with fixed block (18), roating seat (16) are installed to the below of pole setting (11), the outside of roating seat (16) is connected with revolving stage (6), revolving stage (17) have been seted up to the position that just corresponds roating seat (16) on revolving stage (6), the position circumference equipartition that just corresponds fixed block (18) on revolving stage (6) has a plurality of fixed slot (15), two bracing pieces (5), two are installed to the below symmetry of revolving stage (6) the below of bracing piece (5) is fixed with mount table (4).

2. The fiber optic historical building monitoring device of claim 1, wherein: radiator unit (3) include fixing bolt (31), gear motor (32), heat dissipation casing (33), heat dissipation post (34), blade (35), rotation axis (36) and louvre (37), wherein, a plurality of louvre (37) have been seted up to the lower extreme of gear motor (32), the inside of gear motor (32) is leaned on the lower extreme and is connected with rotation axis (36), a plurality of blade (35) are installed in the outside of rotation axis (36), the input shaft end of rotation axis (36) is connected with heat dissipation casing (33), a plurality of heat dissipation post (34) are installed to the top of rotation axis (36), the upper end outward flange circumference equipartition that leans on of gear motor (32) has fixing bolt (31).

3. The fiber optic historical building monitoring device of claim 1, wherein: the mounting base (10) and the upright rod (11) are fixed in a welding mode.

4. The fiber optic historical building monitoring device of claim 1, wherein: the rotating groove (17) is of a smooth structure.

5. A history protection building optical fiber monitoring device according to claim 2, wherein: the last and one end of keeping away from heat dissipation casing (33) of rotation axis (36) of corresponding rotation axis (32) of gear motor (32) has seted up the mounting hole, the last and one end of corresponding rotation axis (36) to be close to heat dissipation casing (33) of gear motor (32) has seted up the perforation, all rotate through the bearing rotation between rotation axis (36) and mounting hole and rotation axis (36) and the perforation and be connected.

6. A history protection building optical fiber monitoring device according to claim 2, wherein: one end of each of the plurality of heat dissipation columns (34) far away from the rotating shaft (36) penetrates through the corresponding through hole (14) and abuts against the lower side wall of the control box (9).

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