CN219697783U - Internet of things monitoring device and system - Google Patents

Abstract

The utility model provides an internet of things monitoring device and system, wherein the device comprises an acquisition module for acquiring image information; an illumination module for providing a light source required for acquiring the image information; the driving module is connected with the acquisition module and used for driving the acquisition module to move; the storage module is used for storing the target parameters and the image information; the processing module is respectively connected with the storage module, the driving module, the acquisition module and the illumination module; the processing module is used for acquiring the image information, and controlling the driving module to drive the acquisition module to move according to the target parameter and the image information; and the defogging module is used for sweeping air towards the lens of the acquisition module so as to remove water mist on the outer surface of the lens. The device is used for continuously tracking the target object and avoiding monitoring dead angles.

Description

Internet of things monitoring device and system

Technical Field

The utility model relates to the technical field of information acquisition, in particular to an internet of things monitoring device and system.

Background

Smart City (Smart City) refers to the application of intelligent computing technologies such as Internet of things, cloud computing, big data, space geographic information integration and the like in the fields of City planning, design, construction, management and operation and the like, so that key infrastructure components and services formed by cities such as City management, education, medical treatment, real estate, transportation, public utilities, public safety and the like are interconnected, efficient and intelligent, thereby providing higher-quality life and working services for citizens, creating a more favorable business development environment for enterprises and enabling a more efficient operation and management mechanism for governments.

At present, building facilities, environmental greening, people flow and biological migration in urban parks all need to be monitored so as to be statistically managed. If the monitoring device is simply dependent on manpower to monitor and cause unnecessary loss, a large amount of manpower can be saved by adopting the monitoring device of the internet of things, disasters or risks can be found in time, and the loss is reduced.

The internet of things monitoring device in the prior art is shown in fig. 1, the field of view of a camera can be blocked by an upright post, and a monitoring dead angle exists. If the monitoring target appears behind the upright post, the monitoring target cannot be perceived, and disasters or risks are not easy to find in time. Therefore, a new internet of things monitoring device and system are needed to improve the above-mentioned problems.

Disclosure of Invention

The utility model aims to provide an Internet of things monitoring device and system, which are used for continuously tracking a target object and avoiding monitoring dead angles.

In a first aspect, the utility model provides an internet of things monitoring device, which comprises an acquisition module, a monitoring module and a monitoring module, wherein the acquisition module is used for acquiring image information; an illumination module for providing a light source required for acquiring the image information; the driving module is connected with the acquisition module and used for driving the acquisition module to move; the storage module is used for storing the target parameters and the image information; the processing module is respectively connected with the storage module, the driving module, the acquisition module and the illumination module; the processing module is used for acquiring the image information, and controlling the driving module to drive the acquisition module to move according to the target parameter and the image information; and the defogging module is used for sweeping air towards the lens of the acquisition module so as to remove water mist on the outer surface of the lens.

The device has the beneficial effects that: according to the utility model, the driving module is controlled by the set processing module to drive the acquisition module to keep facing the target object until the target object is lost, so that the situation that the target object is blocked by the upright post and is lost can be avoided; according to the utility model, the defogging module sweeps air to the lens of the acquisition module so as to remove water mist on the outer surface of the lens, and the condition that a target object is lost due to water mist blocking can be avoided. The method can avoid losing the target object in the monitoring range of the urban park, and is favorable for timely finding disasters or risks.

Optionally, the driving module comprises a support column and a motor; the support column is respectively connected with the acquisition module and a main shaft of the motor; the processing module is connected with the motor and used for controlling the support column and the acquisition module to rotate along the axis of the motor; the axis of the motor is parallel or perpendicular to the central axis of the upright post.

Optionally, the driving module comprises a motor, a first gear and a second gear; the main shaft of the motor is connected with the first gear; the first gear and the second gear are meshed with each other; the second gear is connected with the acquisition module; the processing module is connected with the motor and used for controlling the motor to drive the first gear to rotate so that the second gear and the acquisition module rotate around the axis of the second gear.

Optionally, the demisting module comprises a cavity; the cavity is arranged at the outer side of the motor; the acquisition module comprises a camera; the main shaft of the motor is connected with fan blades, and the motor is used for enabling air in the cavity to flow through the outer surface of the lens of the camera when driving the fan blades to rotate. The beneficial effects of the device are that the heat of the motor is conducted to the outer surface of the lens of the camera by the aid of the fan blade rotation driving air flow, the motor is cooled, the surface of the lens is heated, the service life of the motor is prolonged, and meanwhile, water mist on the outer surface of the lens is removed.

Optionally, the demisting module comprises a first air pipe, a second air pipe, a third air pipe and a fourth air pipe; the first air pipe and the second air pipe are communicated with the cavity; the third air pipe and the fourth air pipe are fixed relative to the second gear; when the first air pipe is communicated with the third air pipe, the second air pipe is communicated with the fourth air pipe; when the first air pipe is communicated with the fourth air pipe, the second air pipe is communicated with the third air pipe.

Optionally, the lighting module includes a first lighting unit and a second lighting unit; the first lighting unit is located higher than the second lighting unit; the illumination area of the first illumination unit surrounds the illumination area of the second illumination unit; the processing module is connected with the second lighting unit and used for controlling the lighting brightness of the second lighting unit. The processing module is used for controlling the second illumination unit to provide illumination when the target object moves from the illumination area of the first illumination unit to the illumination area of the second illumination unit, and the loss of the target object captured by the acquisition module due to insufficient light can be avoided.

Optionally, the system also comprises an alarm module; the processing module is connected with the alarm module and used for controlling the alarm module to give an alarm when the target object is lost.

Optionally, the processing module is configured to start timing when the alarm module sends an alarm, and control the alarm module to release the alarm when the timing reaches a preset time value.

Optionally, the system further comprises a communication module; the processing module is connected with the communication module and used for controlling the communication module to transmit the image information; the communication module is also used for receiving the target parameters.

In a second aspect, the present utility model provides an internet of things monitoring system, including a platform management device and at least two internet of things monitoring devices according to any one of the first aspects; the platform management device is used for adjusting the target parameters.

Drawings

FIG. 1 is a schematic diagram of a prior art structure for installing a camera on a street lamp;

fig. 2 is a schematic structural diagram of an internet of things monitoring device provided by the utility model;

fig. 3 is a schematic structural diagram of an internet of things monitoring device provided with a driving module according to the present utility model;

fig. 4 is a schematic structural diagram of an internet of things monitoring device with the axis of a motor perpendicular to the axis of a stand column;

fig. 5 is a schematic structural diagram of an internet of things monitoring device with the axis of a motor parallel to the axis of a stand column;

fig. 6 is a schematic structural diagram of an internet of things monitoring device with a gear according to the present utility model;

fig. 7 is a schematic structural diagram of an internet of things monitoring device when a housing is located in a first direction of a stand column;

fig. 8 is a schematic structural diagram of an internet of things monitoring device when a housing is located in a second direction of a stand column according to the present utility model;

fig. 9 is a schematic structural diagram of an internet of things monitoring system provided by the utility model.

Reference numerals in the drawings:

10. the monitoring device of the Internet of things; 11. a storage module; 12. a processing module; 13. an acquisition module; 14. a driving module; 141. a motor; 142. a first gear; 143. a second gear; 145. a support column; 15. a lighting module; 151. a first lighting unit; 152. a second lighting unit; 16. a communication module; 17. an alarm module; 21. a main control board; 22. a column; 231. a camera; 232. a housing; 241. a cavity; 242. a fan blade; 31. an air bag; 32. a first air tube; 33. a second air pipe; 34. a third air pipe; 35. a fourth air pipe; 40. the system comprises an Internet of things monitoring system; 41. platform management device.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model. Unless otherwise defined, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this utility model belongs. As used herein, the word "comprising" and the like means that elements or items preceding the word are included in the element or item listed after the word and equivalents thereof without precluding other elements or items.

FIG. 1 is a schematic diagram of a prior art structure for installing a camera on a street lamp;

fig. 2 is a schematic structural diagram of an internet of things monitoring device provided by the utility model.

In order to solve the problems in the prior art, as shown in fig. 2, the utility model provides an internet of things monitoring device 10, which comprises an acquisition module 13 for acquiring image information. An illumination module 15 for providing the light sources required for acquiring said image information. And the driving module 14 is connected with the acquisition module 13 and is used for driving the acquisition module 13 to move. A storage module 11 for storing the target parameters and the image information. The processing module 12 is respectively connected with the storage module 11, the driving module, the acquisition module 13 and the illumination module 15. The processing module 12 is configured to obtain the image information, and control the driving module to drive the acquisition module 13 to move according to the target parameter and the image information. And the defogging module is used for sweeping air to the lens of the acquisition module 13 so as to remove water mist on the outer surface of the lens.

Fig. 3 is a schematic structural diagram of an internet of things monitoring device with a driving module.

As shown in fig. 3, specifically, the acquisition module 13 is a camera 231. The lighting module 15 is an LED lamp. The driving module 14 is a motor 141. The storage module 11 is a memory, and the processing module 12 is a processor. The defogging module is a fan. The motor 141 is fixedly connected with the upright 22. The motor 141 rotates the main shaft to rotate the camera 231 around the column 22.

It should be noted that the number of cameras 231 may be N, where N is any positive integer. The fields of view of the N cameras 231 cover the respective directions of the park to acquire image data of the park.

It should be noted that, the processing module 12 controls the driving module to drive the collecting module 13 to keep facing the target object until the target object is lost, which is beneficial to avoiding the situation that the target object is blocked by the upright 22 and lost. The defogging module sweeps air to the lens of the acquisition module 13 so as to remove water mist on the outer surface of the lens, and the situation that a target object is lost due to water mist blocking can be avoided. The method can avoid losing the target object in the monitoring range of the urban park, and is favorable for timely finding disasters or risks.

In some embodiments, the drive module 14 includes a support column 144 and a motor 141. The support column 144 is connected to the main shaft of the acquisition module 13 and the motor 141, respectively. The processing module 12 is connected with the motor 141, and is used for controlling the support column 144 and the acquisition module 13 to rotate along the axis of the motor 141. The axis of the motor 141 is parallel or perpendicular to the central axis of the upright 22.

Referring to fig. 2 and 3, in some embodiments, the lighting module 15 includes a first lighting unit 151 and a second lighting unit 152. The first illumination unit 151 is located higher than the second illumination unit 152. The illumination area of the first illumination unit 151 surrounds the illumination area of the second illumination unit 152. The processing module 12 is connected to the second lighting unit 152 for controlling the lighting brightness of the second lighting unit 152.

Specifically, the first lighting unit 151 is located at the top end of the pillar 22. When the first lighting unit 151 is lighted, the bottom end of the pillar 22 forms a conical shadow area. The second illumination unit 152 is located within the conical shadow region.

In other embodiments, the processing module 12 is configured to control the second illumination unit 152 to illuminate when the target object enters the conical shadow area, so as to prevent the target object from being lost.

It should be noted that the processing module 12 is configured to control the brightness of the second illumination unit 152 to avoid overexposure of the target object in the image acquired by the acquisition module 13.

Illustratively, when the target object is a wild animal in the park, the processing module 12 is configured to control the magnitude of the increase in brightness of the second lighting unit 152, which is advantageous for avoiding the wild animal in the park from being frightened and for protecting ecology.

In some embodiments, an alarm module 17 is also included. The processing module 12 is connected with the alarm module 17 and is used for controlling the alarm module 17 to give an alarm when the target object is lost.

Specifically, the alarm module 17 is a buzzer. The buzzer is used for sounding an alarm.

In other specific embodiments, the alarm module 17 is an alarm lamp, and the alarm lamp is used for emitting an alarm flash.

It should be noted that, the alarm module 17 is configured to notify the staff of the loss of the target object, so as to remind the staff to enhance patrol.

In still other embodiments, the processing module 12 is configured to start timing when the alarm module 17 issues an alarm, and control the alarm module 17 to release the alarm when the timing reaches a preset time value.

In some embodiments, a communication module 16 is also included. The processing module 12 is connected to the communication module 16 for controlling the communication module 16 to transmit the image information. The communication module 16 is also adapted to receive the target parameter.

Specifically, the target parameters are shape and color information of the target object. The processing module 12 identifies a target object based on the target parameters. The image information is the image information containing the target object, so that the staff can find and observe the target object in time.

Referring to fig. 2 and 3, it should be noted that the storage module 11 and the processing module 12 may be separately provided, or the storage module 11 and the processing module 12 may be provided on a main control board 21.

Fig. 4 is a schematic structural diagram of an internet of things monitoring device with the axis of a motor perpendicular to the axis of a stand column.

As shown in fig. 4, specifically, the axis of the motor 141 is perpendicular to the central axis of the upright 22. The main shaft of the motor 141 is connected with a support column 144. The end of the support column 144 is connected to the acquisition module 13. When the motor 141 is started, the acquisition module 13 rotates along a horizontal axis. The method and the device can capture the object of the flying object in the park, are favorable for air defense and early warning, and acquire bird migration data.

Fig. 5 is a schematic structural diagram of an internet of things monitoring device with the axis of a motor parallel to the axis of a stand column.

In other embodiments, as shown in fig. 5, the axis of the motor 141 is parallel to the central axis of the upright 22. The main shaft of the motor 141 is connected with a support column 144. The end of the support column 144 is connected to the acquisition module 13. When the motor 141 is started, the acquisition module 13 rotates along a vertical axis. The embodiment can capture the target object on the ground surface of the park in any direction, is favorable for eliminating the monitoring dead angle and avoids the target object from being blocked by the upright post 22 to be lost.

Fig. 6 is a schematic structural diagram of an internet of things monitoring device with gears.

In still other embodiments, as shown in fig. 6, the drive module 14 includes a motor 141, a first gear 142, and a second gear 143. The main shaft of the motor 141 is connected to the first gear 142. The first gear 142 is intermeshed with the second gear 143. The second gear 143 is connected to the acquisition module 13. The processing module 12 is connected with the motor 141, and is used for controlling the motor 141 to drive the first gear 142 to rotate, so that the second gear 143 and the acquisition module 13 rotate around the axis of the second gear 143.

Specifically, the motor 141 is fixedly connected to the upright 22. The main shaft of the motor 141 is fixedly connected with the first gear 142. The second gear 143 is rotatably connected to the column 22.

In some embodiments, the demisting module includes a cavity 241. The cavity 241 is provided outside the motor 141. The acquisition module 13 comprises a camera 231. The spindle of the motor 141 is connected with a fan blade 242, and when the motor 141 drives the fan blade 242 to rotate, air in the cavity 241 flows through the outer surface of the lens of the camera 231.

Specifically, a housing 232 is disposed outside the camera 231. The housing 232 is provided in a transparent manner.

In other embodiments, the demister module includes a first air tube 32, a second air tube 33, a third air tube 34, and a fourth air tube 35. The first air pipe 32 and the second air pipe 33 are both communicated with the cavity 241. The third air pipe 34 and the fourth air pipe 35 are fixed relative to the second gear 143. When the first air pipe 32 communicates with the third air pipe 34, the second air pipe 33 communicates with the fourth air pipe 35. When the first air pipe 32 communicates with the fourth air pipe 35, the second air pipe 33 communicates with the third air pipe 34.

Fig. 7 is a schematic structural diagram of an internet of things monitoring device when a shell is located in a first direction of a stand column.

Specifically, a gap exists between the cavity 241 and the motor 141. As shown in fig. 7, the third air pipe 34 and the second air pipe 33 communicate, and the first air pipe 32 and the fourth air pipe 35 communicate. When the fan blade 242 rotates, air flows from the third air pipe 34 and the second air pipe 33 to the gap, and the air flowing through the gap is blown to the lens of the camera 231 through the first air pipe 32 and the fourth air pipe 35.

Fig. 8 is a schematic structural diagram of an internet of things monitoring device when a housing is located in a second direction of a stand column.

In other embodiments, as shown in FIG. 8, the third air tube 34 communicates with the first air tube 32, and the second air tube 33 communicates with the fourth air tube 35. When the fan blade 242 rotates, air flows from the fourth air pipe 35 and the second air pipe 33 to the gap, and the air flowing through the gap is blown to the lens of the camera 231 through the first air pipe 32 and the third air pipe 34.

In yet other embodiments, the first air tube 32, the second air tube 33, the third air tube 34, and the fourth air tube 35 are not in communication with each other. Air flowing through the slit is pressed into the airbag 31 of the first air tube 32, and the airbag 31 is inflated.

In still other embodiments, when the first air tube 32 is in communication with the third air tube 34 or the fourth air tube 35 again, the air bag 31 is contracted and restored, which is advantageous for increasing the air flow to the lens and for improving the defogging effect.

It should be noted that the above embodiment sweeps air from the third air tube 34 and the fourth air tube 35 toward the lens, respectively. The phenomenon that the lens is heated unevenly is avoided, the demisting effect is enhanced, and the lens is prevented from being damaged.

Fig. 9 is a schematic structural diagram of an internet of things monitoring system provided by the utility model.

As shown in fig. 9, the present utility model provides an internet of things monitoring system 40, which includes a platform management device 41 and at least two internet of things monitoring devices 10 according to any of the above embodiments. The platform management device 41 is configured to adjust the target parameter.

Specifically, the number of the monitoring devices 10 of the internet of things is set to 2. When the first internet of things monitoring apparatus 10 captures a first target object according to the first target parameter, the first internet of things monitoring apparatus 101 transmits image information including the first target object to the platform management apparatus 41. The platform management device 41 is configured to adjust the first target parameter to a second target parameter according to the image information. And sends the second target parameter to the first internet of things monitoring device 101 and the second internet of things monitoring device 102, so that the internet of things monitoring device 10 searches for the second target object.

Illustratively, the first target object is configured as a flame. The first target parameter is set to a luminance characteristic. The second target parameter is set as a personality trait. The first internet of things monitoring apparatus 101 transmits image information including flames to the platform management apparatus 41. The platform management device 41 is configured to adjust the brightness characteristic to a character characteristic in the image information according to the image information. And transmits the character feature to the first internet of things monitoring device 10 and the second internet of things monitoring device 10 so that the internet of things monitoring device 10 searches for a fire fighter.

In other examples, the first target object may also be configured as an infectious disease carrier and the first target parameter may be configured as a human characteristic. The second target parameter may be set as a shape feature. The first internet of things monitoring apparatus 101 transmits image information including an infectious disease carrier to the platform management apparatus 41. The platform management device 41 is configured to adjust the character feature to a shape feature in the image information according to the image information. And transmits the character features to the first internet of things monitoring device 101 and the second internet of things monitoring device 102, so that the internet of things monitoring device searches for park facilities contacted by the infectious disease carrier.

It should be noted that, the number of the monitoring devices 10 of the internet of things may be set to any positive integer greater than 2.

While embodiments of the present utility model have been described in detail hereinabove, it will be apparent to those skilled in the art that various modifications and variations can be made to these embodiments. It is to be understood that such modifications and variations are within the scope and spirit of the present utility model as set forth in the following claims. Moreover, the utility model described herein is capable of other embodiments and of being practiced or of being carried out in various ways.

Claims (10)

1. The utility model provides an thing networking monitoring device which characterized in that includes:

the acquisition module is used for acquiring image information;

an illumination module for providing a light source required for acquiring the image information;

the driving module is connected with the acquisition module and used for driving the acquisition module to move;

the storage module is used for storing the target parameters and the image information;

the processing module is respectively connected with the storage module, the driving module, the acquisition module and the illumination module; the processing module is used for acquiring the image information, and controlling the driving module to drive the acquisition module to move according to the target parameter and the image information;

and the defogging module is used for sweeping air towards the lens of the acquisition module so as to remove water mist on the outer surface of the lens.

2. The apparatus of claim 1, wherein the drive module comprises a support column and a motor;

the support column is respectively connected with the acquisition module and a main shaft of the motor; the processing module is connected with the motor and used for controlling the support column and the acquisition module to rotate along the axis of the motor;

the axis of the motor is parallel or perpendicular to the central axis of the upright post.

3. The apparatus of claim 1 or 2, wherein the drive module comprises a motor, a first gear, and a second gear;

the main shaft of the motor is connected with the first gear; the first gear and the second gear are meshed with each other; the second gear is connected with the acquisition module;

the processing module is connected with the motor and used for controlling the motor to drive the first gear to rotate so that the second gear and the acquisition module rotate around the axis of the second gear.

4. The apparatus of claim 3, wherein the demisting module comprises a cavity;

the cavity is arranged at the outer side of the motor; the acquisition module comprises a camera;

the main shaft of the motor is connected with fan blades, and the motor is used for enabling air in the cavity to flow through the outer surface of the lens of the camera when driving the fan blades to rotate.

5. The apparatus of claim 4, wherein the demisting module comprises a first gas tube, a second gas tube, a third gas tube, and a fourth gas tube;

the first air pipe and the second air pipe are communicated with the cavity;

the third air pipe and the fourth air pipe are fixed relative to the second gear;

when the first air pipe is communicated with the third air pipe, the second air pipe is communicated with the fourth air pipe;

when the first air pipe is communicated with the fourth air pipe, the second air pipe is communicated with the third air pipe.

6. The apparatus of claim 1, wherein the lighting module comprises a first lighting unit and a second lighting unit;

the first lighting unit is located higher than the second lighting unit;

the illumination area of the first illumination unit surrounds the illumination area of the second illumination unit;

the processing module is connected with the second lighting unit and used for controlling the lighting brightness of the second lighting unit.

7. The apparatus of claim 1, further comprising an alarm module;

the processing module is connected with the alarm module and used for controlling the alarm module to give an alarm when the target object is lost.

8. The apparatus of claim 7, wherein the processing module is configured to start timing when the alarm module issues an alarm, and to control the alarm module to release the alarm when the timing reaches a preset time value.

9. The apparatus of claim 1, further comprising a communication module;

the processing module is connected with the communication module and used for controlling the communication module to transmit the image information;

the communication module is also used for receiving the target parameters.

10. An internet of things monitoring system, characterized by comprising a platform management device and at least two internet of things monitoring devices according to any one of claims 1 to 9;

the platform management device is used for adjusting the target parameters.