CN215934204U

CN215934204U - Remote monitoring device convenient to maintain

Info

Publication number: CN215934204U
Application number: CN202121593003.2U
Authority: CN
Inventors: 颜龙; 丁宇; 李晓东
Original assignee: Seismological Bureau Of Xinjiang Uygur Autonomous Region
Current assignee: Seismological Bureau Of Xinjiang Uygur Autonomous Region
Priority date: 2021-07-14
Filing date: 2021-07-14
Publication date: 2022-03-01
Anticipated expiration: 2031-07-14

Abstract

The utility model discloses a remote monitoring device convenient to maintain, which comprises a support, a wind-solar hybrid power generation mechanism, a sensor mounting structure, four environmental parameter sensors and a control box. The remote monitoring device convenient to maintain utilizes the box body and the box cover, so that maintenance personnel can conveniently check, maintain and replace components in the control box; the components such as the controller and the like are installed by utilizing the drawer structure, so that maintenance personnel can conveniently draw out for inspection or maintain and replace; the four environmental parameter sensors are mounted by using the sensor mounting box, so that multifunctional monitoring is realized, and the environmental parameter sensors are convenient to replace or maintain; the wind-solar complementary power generation mechanism is used for charging the storage battery through the wind-solar complementary power generation circuit, so that the service life of the storage battery is prolonged, and the detection time of each environmental parameter sensor is prolonged; storing the data acquired by each environmental parameter sensor by using a memory; and uploading the data in the memory to a remote control center by using the wireless communication module.

Description

Remote monitoring device convenient to maintain

Technical Field

The utility model relates to a remote monitoring device, in particular to a remote monitoring device convenient to maintain.

Background

At present, one or two of monitoring equipment adopted in the market, namely humidity, temperature, wind power, coverage rate and rainfall are monitored, so that the technical problem of single function exists, and the equipment cannot be simultaneously applied to safety monitoring in multiple fields; secondly, the monitoring equipment used at present is generally complex in structure, difficult to replace and maintain, inconvenient to use, high in maintenance cost and the like.

SUMMERY OF THE UTILITY MODEL

Utility model purpose: the remote monitoring device convenient to maintain is provided, and has multiple monitoring functions while being convenient to maintain.

The technical scheme is as follows: the utility model provides a remote monitoring device convenient to maintain, which comprises a bracket, a wind-solar hybrid power generation mechanism, a sensor mounting structure, four environmental parameter sensors and a control box, wherein the bracket is used for supporting the wind-solar hybrid power generation mechanism;

the sensor mounting structure comprises a rotary cover cap and a sensor mounting box; the rotary cap is arranged on the upper end of the bracket; the sensor mounting box is mounted on the rotary cap; the four environmental parameter sensors are all arranged on the sensor mounting box; the wind-solar hybrid power generation mechanism is arranged on the bracket and used for realizing solar power generation and wind power generation;

the control box consists of a box body and a box cover; the box body is arranged on the bracket; the box cover is hinged on the box body and is used for covering the opening of the box body; a drawer structure is arranged in the box body;

the drawer structure is provided with a controller, a wind-solar complementary power generation circuit, a power supply circuit, a wireless communication module and a memory; a storage battery is arranged in the box body and below the drawer structure; the wireless communication module, the memory and the four environmental parameter sensors are electrically connected with the controller; the wind-solar complementary power generation mechanism charges the storage battery through the wind-solar complementary power generation circuit; the storage battery supplies power to the controller, the wireless communication module, the memory and the four environmental parameter sensors through the power supply circuit.

Furthermore, a boss is arranged on the upper side surface of the rotary cover cap, and the boss is positioned in the sensor mounting box; the four side surfaces of the sensor mounting box are respectively provided with a mounting window; the four environmental parameter sensors are respectively arranged on the four mounting windows.

Furthermore, a plug-in circuit board is arranged on the boss; four sockets are arranged on the plug-in circuit board; the four environmental parameter sensors are respectively connected with the four plug sockets through plug heads in a conductive manner; the four sockets are all electrically connected with the controller.

Further, the support comprises a lifting structure and a supporting structure; the lifting structure comprises a lifting sleeve and a lifting rod; the lower end of the lifting rod is inserted into the lifting sleeve in an adjustable manner; the rotary cap is arranged on the upper end of the lifting rod; the supporting structure is arranged on the lower end of the lifting sleeve and used for supporting the lifting sleeve.

Further, the supporting structure comprises a bottom plate, four anti-toppling support rods and a counterweight water tank; the lower end of the lifting sleeve is fixed on the upper side surface of the bottom plate; the counterweight water tank is arranged on the bottom plate; the four anti-toppling support rods are respectively fixed on the front, the rear, the left and the right sides of the bottom plate.

Furthermore, the drawer structure comprises a drawer plate and two sliding guide rails; the two sliding guide rails are respectively and symmetrically arranged on the inner walls of the left side and the right side of the box body, and the rear ends of the sliding guide rails are higher than the front ends of the sliding guide rails; the drawer plate is arranged on the two sliding guide rails; and a locking structure is arranged on one of the sliding guide rails and used for locking the drawer plate.

Furthermore, an accommodating groove is formed in the upper side face of the drawer plate; a rectangular hole is formed at the bottom of the accommodating groove; a mounting plate is arranged in the accommodating groove; the controller, the wireless communication module, the memory, the wind-solar hybrid power generation circuit and the power supply circuit are all installed on the installation plate.

Further, the locking structure comprises a locking boss; the front end of one of the sliding guide rails is provided with a mounting hole, the locking convex column is telescopically arranged on the mounting hole, and the front end and the rear end of the corresponding side surface of the drawer plate are respectively provided with two locking holes for the end parts of the locking convex column to extend into.

Furthermore, a limiting sliding chute is transversely arranged on the wall of the mounting hole; the extending end of the locking convex column is provided with a sliding block which is in sliding fit with the limiting sliding groove.

Further, the wind-solar hybrid power generation mechanism comprises a solar cell panel, a wind driven generator and a height adjusting mechanism: the height adjusting mechanism comprises a height adjusting sleeve and a supporting cantilever; the height adjusting sleeve is adjustably sleeved on the lifting rod; one end of the supporting cantilever is fixed on the height adjusting sleeve; the solar panel is arranged on the other end of the supporting cantilever through the solar mounting plate; the wind driven generator is arranged on the supporting cantilever through the supporting rod; the solar cell panel and the wind driven generator charge the storage battery through the wind-solar hybrid power generation circuit.

Compared with the prior art, the utility model has the beneficial effects that: the box body and the box cover are utilized, so that maintenance personnel can conveniently check, maintain and replace components in the control box; the components such as the controller and the like are installed by utilizing the drawer structure, so that maintenance personnel can conveniently draw out for inspection or maintain and replace; the four environmental parameter sensors are mounted by using the sensor mounting box, so that multifunctional monitoring is realized, and the environmental parameter sensors are convenient to replace or maintain; the wind-solar complementary power generation mechanism is used for charging the storage battery through the wind-solar complementary power generation circuit, so that the service life of the storage battery is prolonged, and the detection time of each environmental parameter sensor is prolonged; storing the data acquired by each environmental parameter sensor by using a memory; and uploading the data in the memory to a remote control center by using the wireless communication module.

Drawings

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

FIG. 2 is a cross-sectional view of a sensor mounting cartridge of the present invention;

FIG. 3 is a cross-sectional view of the locking structure of the present invention;

FIG. 4 is a perspective view of the control box of the present invention;

fig. 5 is a schematic circuit structure of the present invention.

Detailed Description

The technical solution of the present invention is described in detail below with reference to the accompanying drawings, but the scope of the present invention is not limited to the embodiments.

Example 1:

as shown in fig. 1 to 5, the present invention provides a remote monitoring apparatus for facilitating maintenance, including: the wind-solar hybrid power generation system comprises a bracket, a wind-solar hybrid power generation mechanism, a sensor mounting structure, four environmental parameter sensors 15 and a control box;

the sensor mounting structure comprises a rotary cap 10 and a sensor mounting box 12; a rotary cap 10 is installed on the upper end of the bracket; the sensor mounting box 12 is mounted on the rotary cap 10; the four environmental parameter sensors 15 are all arranged on the sensor mounting box 12; the wind-solar hybrid power generation mechanism is arranged on the bracket and used for realizing solar power generation and wind power generation;

the control box consists of a box body 35 and a box cover 36; the box body 35 is arranged on the bracket; the box cover 36 is hinged on the box body 35 through two hinges 17 and is used for covering the opening of the box body 35; a drawer structure is arranged in the box body 35;

the drawer structure is provided with a controller, a wind-solar complementary power generation circuit, a power supply circuit, a wireless communication module and a memory; a storage battery is arranged in the box body 35 and below the drawer structure; the wireless communication module, the memory and the four environmental parameter sensors 15 are all electrically connected with the controller; the wind-solar complementary power generation mechanism charges the storage battery through the wind-solar complementary power generation circuit; the storage battery supplies power to the controller, the wireless communication module, the memory and the four environmental parameter sensors 15 through the power supply circuit.

The box body 35 and the box cover 36 are used for facilitating the inspection, maintenance and replacement of components in the control box by maintenance personnel; the components such as the controller and the like are installed by utilizing the drawer structure, so that maintenance personnel can conveniently draw out for inspection or maintain and replace; the four environmental parameter sensors 15 are mounted by the sensor mounting box 12, so that multifunctional monitoring is realized, and the environmental parameter sensors 15 are convenient to replace or maintain; the wind-solar complementary power generation mechanism is used for charging the storage battery through the wind-solar complementary power generation circuit, so that the service life of the storage battery is prolonged, and the detection time of each environmental parameter sensor 15 is prolonged; the data collected by each environmental parameter sensor 15 is stored by a memory; and uploading the data in the memory to a remote control center by using the wireless communication module.

Further, a boss 13 is arranged on the upper side surface of the rotary cap 10, and the boss 13 is positioned in the sensor mounting box 12; a cover bolt 14 with one end part screwed on the boss 13 is arranged on the circumferential side surface of the rotary cap 10; a mounting window 22 is arranged on each of the front, rear, left and right side surfaces of the sensor mounting box 12; the four environmental parameter sensors 15 are respectively mounted on the four mounting windows 22.

The sensor mounting box 12 is tightly pressed on the boss 13 through the covering bolt 14 by utilizing the matching among the covering bolt 14, the boss 13 and the sensor mounting box 12, so that the mounting reliability of the sensor mounting box 12 is ensured, and the environmental parameter sensor 15 is convenient to mount, dismount or replace; the matching between the boss 13 and the sensor mounting box 12 is utilized to play a certain role of water and moisture prevention.

Further, a plug-in circuit board 20 is mounted on the boss 13; four sockets 23 are provided on the circuit board 20; the four environmental parameter sensors 15 are respectively connected with the four plug sockets 23 through plug connectors in a conductive manner; four of the sockets 23 are electrically connected to the controller.

The environmental parameter sensor 15 mounted on the sensor mounting box 12 is electrically connected to the controller by cooperation between the circuit board 20, the socket 23 and the cartridge head, so that the environmental parameter sensor 15 can be easily replaced.

Further, the support comprises a lifting structure and a supporting structure; the lifting structure comprises a lifting sleeve 8 and a lifting rod 49; the lower end of the lifting rod 49 is inserted in the lifting sleeve 8; a plurality of adjusting holes 7 are arranged on the lifting rod 49 at intervals; a positioning bolt 9 is installed at the upper pipe orifice of the lifting sleeve 8, and the positioning bolt 9 is inserted into one of the adjusting holes 7; the rotary cap 10 is mounted on the upper end of the lifting rod 49; a rotation locking bolt 11 for pressing the lifting rod 49 is installed on the rotation cap 10; the support structure is mounted on the lower end of the lifting sleeve 8 for supporting the lifting sleeve 8.

The height position of the sensor mounting structure is adjusted by utilizing the matching among the lifting sleeve 8, the lifting rod 49, the positioning bolt 9 and the plurality of adjusting holes 7, so that the adjustment of the height position of the environmental parameter sensor 15 is realized; the rotary cap 10 is rotatably arranged at the upper end of the lifting rod 49, so that the orientation of each environmental parameter sensor 15 can be adjusted; the lifting rod 49 is pressed by the rotation locking bolt 11, and the rotation cap 10 is locked in rotation after the adjustment is finished; the support of the supporting lifting sleeve 8 is achieved by means of a support structure.

Further, the support structure comprises a bottom plate 48, four anti-toppling support rods 32 and a counterweight water tank 30; the lower end of the lifting sleeve 8 is fixed at the center of the upper side surface of the bottom plate 48; the counterweight water tank 30 is mounted on the bottom plate 48, and the counterweight water tank 30 surrounds the lifting sleeve 8; one ends of the four anti-toppling stay bars 32 are respectively fixed on the front, rear, left and right sides of the bottom plate 48; a pressing plate 33 is mounted on the other end of each anti-toppling brace 32.

The lifting sleeve 8 is supported in multiple directions by the cooperation of the bottom plate 48, the four anti-toppling support rods 32 and the four pressing plates 33, so that the supporting range is enlarged, and the lifting sleeve 8 is prevented from toppling; the weight of the bottom plate 48 is increased by filling water into the counterweight water tank 30, and the anti-toppling effect is enhanced.

Further, the drawer structure includes a drawer plate 38 and two slide rails 37; the two sliding guide rails 37 are respectively and symmetrically arranged on the inner walls of the left side and the right side of the box body 35, and the rear ends of the sliding guide rails 37 are higher than the front ends; a slide rail groove 53 is formed on each of the opposite surfaces of the two slide rails 37 along the length direction; the edges of the left side and the right side of the drawer plate 38 are respectively inserted on the two slide rail grooves 53; a locking structure is mounted on one of the sliding guide rails 37 for locking the drawer plate 38; a handle 16 is mounted on the front edge of the drawer panel 38.

By utilizing the matching between the two sliding guide rails 37 and the drawer plate 38, the components mounted on the drawer plate 38 can be conveniently replaced or repaired by a maintenance worker; the front end of the handle 16 and the sliding guide rail 37 is shorter than the rear end, so that the drawer plate 38 can be conveniently drawn out; the drawer plate 38 is prevented from slipping out by the locking structure.

Further, an accommodating groove 39 is formed on the upper side surface of the drawer plate 38; a rectangular hole 40 is arranged at the bottom of the accommodating groove 39; a mounting plate 52 is arranged in the accommodating groove 39, and a plurality of air holes 51 are arranged on the mounting plate 52; the controller, wireless communication module, memory, wind-solar hybrid power generation circuit, and power supply circuit are all mounted on the mounting board 52.

The mounting plate 52 is convenient to take out by utilizing the matching between the accommodating groove 39 and the mounting plate 52, so that components on the mounting plate 52 are maintained; the rectangular holes 40 and the plurality of air holes 51 are used for facilitating heat dissipation of the components on the mounting plate 52.

Further, the locking structure includes a locking post 42; a mounting hole 44 is formed in the bottom of one of the slide rail grooves 53 at the front side, one end of the locking convex column 42 extends into the mounting hole 44, and a locking hole 41 for the locking convex column 42 to extend into is formed in each of the front end and the rear end of the corresponding side of the drawer plate 38; a spring hole 46 is arranged on the end surface of the extending end of the locking convex column 42; a locking spring 43 is elastically supported between the bottom of the spring hole 46 and the bottom of the mounting hole 44; the end surface of the other end of the locking convex column 42 is a cambered surface.

The locking convex column 42 is pressed into one of the locking holes 41 by the locking spring 43 acting on the bottom of the spring hole 46, so that the drawer plate 38 is locked, and the drawer plate 38 is ensured not to be separated from the slide rail groove 53 in the drawing state, so that the locking is realized.

Further, a limiting sliding groove 45 is transversely arranged on the wall of the mounting hole 44; a slide block 47 which is in sliding fit with the limit sliding groove 45 is arranged at the extending end of the locking convex column 42.

The locking convex column 42 is ensured to be always inserted in the mounting hole 44 by utilizing the matching between the limiting sliding groove 45 and the sliding block 47, and is prevented from falling off.

Further, the wind-solar hybrid power generation mechanism comprises a solar cell panel 4, a wind driven generator 1 and a height adjusting mechanism: the height adjusting mechanism comprises a height adjusting sleeve 5 and a supporting cantilever 3; the height adjusting sleeve 5 is sleeved on the lifting rod 49; a height adjusting bolt 6 is arranged on the height adjusting sleeve 5, and the height adjusting bolt 6 is inserted in one adjusting hole 7; one end of the supporting cantilever 3 is fixed on the height adjusting sleeve 5; the solar cell panel 4 is mounted on the other end of the support cantilever 3 through a solar mounting plate 51; the wind driven generator 1 is arranged on a supporting cantilever 3 through a supporting rod 2; the solar cell panel 4 and the wind driven generator 1 charge the storage battery through the wind-solar hybrid power generation circuit.

The wind driven generator 1 and the solar panel 4 are used for forming complementation, so that the storage battery can be charged through the wind-solar complementary power generation circuit when wind or light exists, and the detection time of each environmental parameter sensor 15 is prolonged; the height adjustment of the wind driven generator 1 and the height adjustment of the solar cell panel 4 are realized by utilizing the matching among the height adjusting bolt 6, the adjusting hole 7 and the height adjusting sleeve 5, so that the electric energy conversion efficiency is improved.

In the remote monitoring device convenient to maintain, the controller adopts the prior ARM controller module and is used for realizing coordination control; the wireless communication module adopts the existing wireless communication module and is used for uploading data to the remote control center; the memory adopts the existing memory and is used for storing the data acquired by each environmental parameter sensor 15; the four environmental parameter sensors 15 adopt four digital sensors, namely, a temperature sensor, a humidity sensor, an air pressure sensor and a light sensor, which are used for acquiring data.

When the remote monitoring device convenient for maintenance is installed and used, the box cover 36 is firstly opened, the drawer plate 38 is drawn out through the handle 16, the cambered surface of the locking convex column 42 is separated from the locking hole 41 on the front side and then pressed on the side edge of the drawer plate 38 until the locking convex column 42 is pressed into the locking hole 41 on the rear side by the locking spring 43; the controller, the wireless communication module, the wind-solar hybrid power generation circuit, the power supply circuit and the memory are installed on the installation plate 52, the installation plate 52 is placed in the containing groove 39, the drawer plate 38 is pushed back into the box body 35, the cambered surface of the locking convex column 42 is separated from the locking hole 41 on the rear side and then pressed on the side edge of the drawer plate 38 until the locking convex column 42 is pressed into the locking hole 41 on the front side by the locking spring 43, and locking is completed; then the remote monitoring device is placed at the position to be monitored, and then the weighted water tank 30 is filled with water; then adjusting the extension length of the lifting rod 49 until the four environmental parameter sensors 15 reach the specified height position, and then inserting the positioning bolts 9 on the corresponding adjusting holes 7; then the rotary cap 10 is rotated until the four environmental parameter sensors 15 are rotated to the designated orientation, and then the rotary locking bolt 11 is tightened; and finally, adjusting the position of the height adjusting sleeve 5, and inserting the height adjusting sleeve 5 on the corresponding adjusting hole 7 when the wind driven generator 1 and the solar panel 4 reach the specified height.

As noted above, while the present invention has been shown and described with reference to certain preferred embodiments, it is not to be construed as limited thereto. Various changes in form and detail may be made therein without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims

1. A remote monitoring device convenient to maintain, its characterized in that: the wind-solar hybrid power generation system comprises a bracket, a wind-solar hybrid power generation mechanism, a sensor mounting structure, four environmental parameter sensors (15) and a control box;

the sensor mounting structure comprises a rotary cover cap (10) and a sensor mounting box (12); a rotary cap (10) is mounted on the upper end of the bracket; the sensor mounting box (12) is mounted on the rotary cap (10); the four environmental parameter sensors (15) are all arranged on the sensor mounting box (12); the wind-solar hybrid power generation mechanism is arranged on the bracket and used for realizing solar power generation and wind power generation;

the control box consists of a box body (35) and a box cover (36); the box body (35) is arranged on the bracket; the box cover (36) is hinged on the box body (35) and is used for covering the opening of the box body (35); a drawer structure is arranged in the box body (35);

the drawer structure is provided with a controller, a wind-solar complementary power generation circuit, a power supply circuit, a wireless communication module and a memory; a storage battery is arranged in the box body (35) and below the drawer structure; the wireless communication module, the memory and the four environmental parameter sensors (15) are electrically connected with the controller; the wind-solar complementary power generation mechanism charges the storage battery through the wind-solar complementary power generation circuit; the storage battery supplies power to the controller, the wireless communication module, the memory and the four environmental parameter sensors (15) through the power supply circuit.

2. The remote monitoring device of claim 1, wherein: a boss (13) is arranged on the upper side surface of the rotary cap (10), and the boss (13) is positioned in the sensor mounting box (12); a mounting window (22) is arranged on each of the front, rear, left and right side surfaces of the sensor mounting box (12); the four environmental parameter sensors (15) are respectively arranged on the four mounting windows (22).

3. The remote monitoring device of claim 2, wherein: the boss (13) is provided with a plug-in circuit board (20); four plug sockets (23) are arranged on the plug circuit board (20); the four environmental parameter sensors (15) are respectively connected with the four plug sockets (23) through plug heads in a conductive manner; the four sockets (23) are all electrically connected with the controller.

4. The remote monitoring device of claim 1, wherein: the bracket comprises a lifting structure and a supporting structure; the lifting structure comprises a lifting sleeve (8) and a lifting rod (49); the lower end of the lifting rod (49) is inserted into the lifting sleeve (8) in an adjustable manner; the rotary cap (10) is arranged on the upper end of the lifting rod (49); the support structure is mounted on the lower end of the lifting sleeve (8) and is used for supporting the lifting sleeve (8).

5. The remote monitoring device of claim 4, wherein: the supporting structure comprises a bottom plate (48), four anti-toppling support rods (32) and a counterweight water tank (30); the lower end of the lifting sleeve (8) is fixed on the upper side surface of the bottom plate (48); the counterweight water tank (30) is arranged on the bottom plate (48); four anti-toppling support rods (32) are respectively fixed on the front, the rear, the left and the right sides of the bottom plate (48).

6. The remote monitoring device of claim 1, wherein: the drawer structure comprises a drawer plate (38) and two sliding guide rails (37); the two sliding guide rails (37) are respectively and symmetrically arranged on the inner walls of the left side and the right side of the box body (35), and the rear ends of the sliding guide rails (37) are higher than the front ends; the drawer plate (38) is arranged on the two sliding guide rails (37); a locking structure is mounted on one of the sliding guide rails (37) for locking the drawer plate (38).

7. The remote monitoring device of claim 6, wherein: an accommodating groove (39) is arranged on the upper side surface of the drawer plate (38); a rectangular hole (40) is arranged at the bottom of the accommodating groove (39); a mounting plate (52) is arranged in the containing groove (39); the controller, the wireless communication module, the memory, the wind-solar hybrid power generation circuit and the power supply circuit are all installed on the installation plate (52).

8. The remote monitoring device of claim 6, wherein: the locking structure comprises a locking stud (42); the front end of one of the sliding guide rails (37) is provided with a mounting hole (44), the locking convex column (42) is telescopically arranged on the mounting hole (44), and the front end and the rear end of the corresponding side surface of the drawer plate (38) are respectively provided with two locking holes (41) for the end parts of the locking convex column (42) to extend into.

9. The remote monitoring device of claim 8, wherein: a limiting sliding groove (45) is transversely arranged on the wall of the mounting hole (44); a slide block (47) which is in sliding fit with the limit sliding groove (45) is arranged at the extending end of the locking convex column (42).

10. The remote monitoring device of claim 1, wherein: the wind-solar hybrid power generation mechanism comprises a solar cell panel (4), a wind driven generator (1) and a height adjusting mechanism: the height adjusting mechanism comprises a height adjusting sleeve (5) and a supporting cantilever (3); the height adjusting sleeve (5) is sleeved on the lifting rod (49) in an adjustable manner; one end of the supporting cantilever (3) is fixed on the height adjusting sleeve (5); the solar cell panel (4) is arranged at the other end of the supporting cantilever (3) through a solar mounting plate (51); the wind driven generator (1) is arranged on the supporting cantilever (3) through the supporting rod (2); the solar cell panel (4) and the wind driven generator (1) charge the storage battery through the wind-solar hybrid power generation circuit.