CN220187734U - Intelligent sensing sensor for high-pole lamp of port - Google Patents

Abstract

A port high-pole lamp intelligent sensing sensor belongs to the technical field of sensors, and a high-pole lamp sensing window and an optical filter are arranged on the upper surface of a shell. The upper side of the shell is provided with a solar charging panel and a solar ray sensing window. The control part comprises a first photosensitive sensor, a second photosensitive sensor, a camera, a singlechip and a lithium battery. The first photosensitive sensor is arranged below the induction window of the high-pole lamp. The second photosensor is arranged below the solar ray sensing window. The camera is arranged below the optical filter. The first photosensitive sensor is connected with a first AD interface of the singlechip. The second photosensitive sensor is connected with a second AD interface of the singlechip. The camera is connected with a first data receiving-transmitting interface of the singlechip. The communication antenna is connected with a second data receiving and transmitting interface of the singlechip through the wireless communication module. The night field inspection system solves the problem that a large amount of inspection work is performed in the night field, and the main technical state of the high-pole lamp can be monitored through the state of system transmission. The daily inspection cost is reduced.

Description

Intelligent sensing sensor for high-pole lamp of port

Technical field:

the utility model belongs to the technical field of sensors, and particularly relates to an intelligent sensing sensor for a harbour high-pole lamp.

The background technology is as follows:

in the 24-hour working environment of the port, the illumination in the field mainly adopts a high-pole lamp to realize the night illumination function. The technical state of the high-pole lamp is an important facility for guaranteeing the night production safety of ports. Because the service environment, the service life and the external interference of the high-pole lamp source can influence the working state of the high-pole lamp, wharf workers can check the high-pole lamp at night, however, the wharf yard space is huge, the inspection is time-consuming and labor-consuming, the inspection workers can hurt eyes due to the intensity of the light source, the operation safety can be influenced if the inspection is not in place, and even production accidents can be caused.

Disclosure of Invention

The utility model aims to provide a port high-pole lamp intelligent sensing sensor which can replace manual inspection and monitor and sense the state of the high-pole lamp in real time.

The technical scheme adopted is as follows:

the intelligent sensing sensor for the port high-pole lamp comprises a shell and a control part. The method is characterized in that:

the upper surface of the shell is provided with a high-pole lamp induction window and an optical filter.

The upper side of the shell is provided with a solar charging panel and a solar ray sensing window.

A control part is arranged in the shell.

The control part comprises a first photosensitive sensor, a second photosensitive sensor, a camera, a singlechip and a lithium battery.

The first photosensitive sensor is arranged below the induction window of the high-pole lamp.

The second photosensor is arranged below the solar ray sensing window.

The camera is arranged below the optical filter.

The first photosensitive sensor is connected with a first AD interface of the singlechip.

The second photosensitive sensor is connected with a second AD interface of the singlechip.

The camera is connected with a first data receiving-transmitting interface of the singlechip.

The communication antenna is connected with a second data receiving and transmitting interface of the singlechip through the wireless communication module.

The solar charging plate is connected with the lithium battery, and the lithium battery is connected with the single-chip power supply interface through the voltage reduction module.

The advantages are that:

the night field inspection system solves the problem that a large amount of inspection work is performed in the night field, and the main technical state of the high-pole lamp can be monitored through the state of system transmission. The daily inspection cost is reduced. Adopts a solar power supply mode, and is energy-saving and environment-friendly. The high-pole lamp source state acquired in real time can assist production operation, optimize operation route and reduce night production operation risk, thereby realizing the purposes of safe production, energy conservation and emission reduction.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a cross-sectional view of the present utility model.

Fig. 3 is a schematic circuit diagram of the present utility model.

In the figure: 1 mount, 2 high pole lamp response window, 3 light filter, 4 solar ray response window, 5 solar charging panel, 6 shell, 7 communication antenna, 8 first photosensitive sensor, 9 second photosensitive sensor, 10 cameras, 11 main circuit board, 12 lithium cell, 13 magnet.

Detailed Description

The intelligent sensor for the harbour high-pole lamp comprises a shell 6 and a control part.

The upper surface of the shell 6 is provided with a high-pole lamp induction window 2 and an optical filter 3.

The upper side of the shell 6 is provided with a solar charging panel 5 and a solar ray sensing window 4.

A control part is provided in the housing 6.

The control section includes: the device comprises a first photosensitive sensor 8, a second photosensitive sensor 9, a camera 10, a singlechip, a main circuit board 11 and a lithium battery 12.

The first photosensor 8 is arranged below the high-pole lamp induction window 2.

The second photosensor 9 is disposed below the solar ray sensing window 4.

The camera 10 is disposed below the filter 3.

The communication antenna 7 may be disposed below and outside the housing 6.

The magnet 13 is arranged outside the shell 6, the shell 6 and the fixing frame 1 are fixed through screws, and the fixing frame 1 is sucked and fixed below the high-pole lamp through the magnet 13 (neodymium magnet) and is located at a position about 2 meters away from the ground. The housing 6 can be replaced according to the column shape of the high-pole lamp.

The housing 6 may be a metal housing.

The camera 10 may be an industrial camera.

A high efficiency lithium battery may be employed for longer use of the lithium battery 12.

The filter 3 is a light-reducing filter.

The model of the singlechip is STM8S105 or ATmega328P.

The installation angle of the solar ray sensing window 4 and the high-pole lamp sensing window 2 is 120-125 degrees.

Specific angles may be 120 degrees, 123 degrees, or 125 degrees.

The first photosensitive sensor 8 is connected with a first AD interface of the singlechip.

The second photosensitive sensor 9 is connected with a second AD interface of the singlechip.

The camera 10 (CCD) is connected with a first data receiving and transmitting interface of the singlechip. The singlechip supplies power to the camera 10.

The communication antenna 7 (ANT) is connected with the second data transceiver interface of the singlechip through a wireless communication module. The singlechip supplies power to the wireless communication module.

The solar charging panel 5 is connected with the lithium battery 12, and the lithium battery 12 is connected with a singlechip power supply interface through a voltage reduction module.

The step-down module powers the first photo-sensor 8 and the second photo-sensor 9.

The lithium battery 12 supplies power to the portions that need to be powered.

The step-down module, the wireless communication module and the singlechip are arranged on the main circuit board 11.

The induction window 2 and the optical filter 3 of the high-pole lamp are arranged towards the direction of the lamp.

The first photosensor 8 and the second photosensor 9 are both photoresistors.

The sensor mainly comprises modules such as light sense, communication, video analysis (in a singlechip) and the like, is a sensor which can be used for monitoring the working state of a high-pole lamp at night, has the functions of automatically charging in daytime, monitoring the illumination intensity of the high-pole lamp at night, the illumination time of the sun and monitoring the fault of a lamp source, and transmits the monitoring state to a control or monitoring center so as to realize the purpose of replacing manual inspection and real-time monitoring and sensing. Can adapt to the high-pole lamp with different diameters and column shapes.

The light sensing module (the first photosensitive sensor 8 and the second photosensitive sensor 9) is adopted for environmental sampling, the working state of the high-pole lamp is interpreted, and the long-period working problem is solved through solar power supply. The light-reducing filter sheet 3 is additionally arranged outside the camera 10 to collect core spots of the light source, and the technical state of the high-pole lamp is judged through the data processing and comparison of the singlechip. And transmits the information to the monitoring center through the wireless module (communication antenna 7).

The solar charging panel 5 is mainly used for charging the lithium battery 12 by solar energy, and the solar illumination intensity is sensed by the two photosensitive sensors in the solar ray sensing window 4 and the high-pole lamp sensing window 2 in the daytime, so that the two photosensitive sensors do not work. Because the setting angle of the solar ray sensing window 4 and the high-pole lamp sensing window 2 is 120-125 ℃, the second photosensitive sensor 9 in the solar ray sensing window 4 can not sense illumination after sunset, and at the moment, the two photosensitive sensors start to work.

The optical filter 3 mainly plays a role in filtering and reducing the light source intensity, the camera 10 shoots the state of the high-pole lamp light source through the optical filter 3, the singlechip of the main circuit board 11 is used for calculating the position of the light source, if the high-pole lamp light source fails, the camera 10 cannot read the failure light source signal, and the system collects the failure light source signal through the singlechip and sends the failure light source signal to the control center or the monitoring center from the communication antenna 7.

The first photosensitive sensor 8 can sense the intensity of the working chamber optical fiber of the high-pole lamp at night, if the intensity is reduced, the problems of power supply and the like can be interpreted, and the state is processed by the singlechip and then is sent to the control center or the monitoring center through the communication antenna 7.

The high beam lamp is composed of a plurality of lamp caps, and the camera 10 recognizes the normal number of lamp caps. If one of the lamps is extinguished due to a fault, the camera 10 compares the lamp head change to determine whether the group of high-pole lamps has a fault. The camera 10 is additionally provided with the dimming filter, so that the illumination intensity is reduced, the state of a normal lamp holder of the high-pole lamp can be identified, if the lamp holder is extinguished due to faults, the number of the lamp holder is reduced by one by adopting the picture identified by the serial port camera 10, the fault judgment of the high-pole lamp and the lamp holder with specific position problems can be realized through the calculation of the single chip microcomputer, and the fault judgment of a plurality of lamps on the high-pole lamp can be realized.

Claims (6)

1. The intelligent sensing sensor of the port high-pole lamp comprises a shell (6) and a control part; the method is characterized in that:

the upper surface of the shell (6) is provided with a high-pole lamp induction window (2) and an optical filter (3);

a solar charging plate (5) and a solar ray induction window (4) are arranged on the upper side surface of the shell (6);

a control part is arranged in the shell (6);

the control part comprises a first photosensitive sensor (8), a second photosensitive sensor (9), a camera (10), a singlechip and a lithium battery (12);

the first photosensitive sensor (8) is arranged below the induction window (2) of the high-pole lamp;

the second photosensitive sensor (9) is arranged below the solar ray sensing window (4);

the camera (10) is arranged below the optical filter (3);

the first photosensitive sensor (8) is connected with a first AD interface of the singlechip;

the second photosensitive sensor (9) is connected with a second AD interface of the singlechip;

the camera (10) is connected with a first data receiving-transmitting interface of the singlechip;

the communication antenna (7) is connected with a second data receiving and transmitting interface of the singlechip through the wireless communication module;

the solar charging plate (5) is connected with the lithium battery (12), and the lithium battery (12) is connected with the single-chip power supply interface through the voltage reduction module.

2. The harbour overhead light intelligent perception sensor of claim 1, wherein:

the communication antenna (7) is arranged on the outer side below the shell (6).

3. The harbour overhead light intelligent perception sensor of claim 1, wherein:

the camera (10) is an industrial camera.

4. The harbour overhead light intelligent perception sensor of claim 1, wherein:

a magnet (13) is arranged outside the shell (6).

5. The harbour overhead light intelligent perception sensor of claim 1, wherein:

the model of the singlechip is STM8S105 or ATmega328P.

6. The harbour overhead light intelligent perception sensor of claim 1, wherein:

the first photosensor (8) and the second photosensor (9) are photoresistors.