CN113993258A - Wisdom street lamp with trouble self-checking function - Google Patents

Abstract

The invention relates to a smart street lamp with a fault self-checking function, wherein when a processor is executed, an upper computer instructs the processor to further determine which street lamp is a fault light source of a lamp of the street lamp, firstly, a first smart sensor in a plurality of smart sensors is identified, the first smart sensor is coupled to the street lamp with the fault light source, then, a second smart sensor in the plurality of smart sensors is identified, the second smart sensor is coupled to a second street lamp in the plurality of street lamps and is close to the first smart sensor, the first smart sensor is indicated to reduce the use of the street lamp with the fault light source, and the second smart sensor is indicated to increase the use of a working light source of the second street lamp. The invention has the advantages that: the light source near the fault street lamp is balanced, people are reminded of overhauling in time, and the form safety of the road is guaranteed.

Description

Wisdom street lamp with trouble self-checking function

Technical Field

The invention relates to the technical field of street lamps, in particular to an intelligent street lamp with a fault self-checking function.

Background

When the short circuit and the open circuit of the street lamp are in fault, the maintenance method to be adopted is selected according to the type of the street lamp and the comprehensive condition of the street lamp. The problem of the street lamp can be effectively solved by selecting a correct troubleshooting mode, and the service life of the street lamp is prolonged. The existing street lamp has problems, and the short-circuit fault direct-current resistance detection method and the capacitance current-limiting method are basically adopted to detect which specific street lamp has problems, but the structure can be obtained only by checking the street lamp with high consciousness, so that the street lamp with faults can not be used, and the trip of people in the fault area is influenced.

Disclosure of Invention

The invention provides an intelligent street lamp with a fault self-checking function.

In order to solve the technical problems, the technical scheme provided by the invention is as follows: a smart street light with fault self-checking functionality comprising a plurality of smart sensors coupled to respective street light devices of a plurality of street lights, each smart sensor comprising a memory for storing data, a processor based monitoring circuit, a processor for receiving data captured by one or more sensors and storing the received data in the memory, the processor for executing host computer instructions; when executed, the processor aggregates stored data from the plurality of smart sensors and generates a current data signature, compares the current data signature to a plurality of known signatures, identifies a fault event affecting at least one of the plurality of street lights based on the comparison between the current data signature and the plurality of known signatures, and performs an operation according to the identified fault event; when executed by the processor, the upper computer instructs the processor to further determine which street light fixture has a faulty light source for the identified event, first identify a first smart sensor of the plurality of smart sensors coupled to the street light having the faulty light source, and then identify a second smart sensor of the plurality of smart sensors coupled to a second street light of the plurality of street lights and proximate to the first smart sensor, instruct the first smart sensor to decrease use of the street light having the faulty light source, and instruct the second smart sensor to increase use of the second street light operating light source.

After adopting the structure, the invention has the following advantages: the street lamp fault condition relevant to the independent recognition, and rationally arrange corresponding street lamp operating time according to the fault condition to strengthen the illumination light source of the street lamp that is close to the fault street lamp, in order to make the light source near the fault street lamp balanced as far as possible, show the personnel of managing the host computer by the host computer, can remind people in time to overhaul, guarantee the safety of going of road.

Detailed Description

The present invention is described in further detail below.

An intelligent street lamp with fault self-checking function comprises a plurality of intelligent sensors coupled to corresponding street lamp devices of the plurality of street lamps, the intelligent sensors can operate as small cellular network equipment to provide wireless cellular based network communication service, the intelligent sensor equipment can collect data related to the communication service, including but not limited to signal strength, signal quality, data throughput, number of active users of a wireless network and the like; this wireless network communication data can be used to track the overall state of the network; each smart sensor includes a memory for storing data, a processor-based monitoring circuit, a processor for receiving data captured by one or more sensors and storing the received data in the memory, where the collected data includes, but is not limited to, tilt sensor data, accelerometer data, temperature data, power metering data, camera images or video, sound data, humidity sensor data, rain collection data, wind collection data, air quality data, or other data and light poles that may monitor the smart sensor device itself, the street light fixture to which the smart sensor device is connected, the light pole to which the respective street light fixture is connected, or the environment around the smart sensor device and the respective street light fixture; the processor is used for executing the upper computer instructions; when executed, the processor aggregates stored data from the plurality of smart sensors and generates a current data signature, compares the current data signature to a plurality of known signatures, identifies a fault event affecting at least one of the plurality of street lights based on the comparison between the current data signature and the plurality of known signatures, and performs an operation according to the identified fault event; when executed by the processor, the host computer instructing the processor to further determine which of the street light fixtures is a faulty light source for the identified event, the faulty light source may be a power consumption threshold set based on an amount of power expected to be consumed by the light source when illuminated, and when comparing the current data signature to the faulty light source signature, if the monitored data indicates that the power consumption is below the power consumption threshold, a match may occur between the current data signature and the known faulty light source signature, whereupon the host computer may take action to first identify a first one of the plurality of smart sensors coupled to the street light having the faulty light source and then identify a second one of the plurality of smart sensors coupled to and proximate to a second one of the plurality of street lights as if the light source in the street light fixture coupled to the smart sensor device that captured the data failed, and instructing the first intelligent sensor to reduce the use of the street lamp with the fault light source, and instructing the second intelligent sensor to increase the use of the working light source of the second street lamp.

The instructions for the first smart sensor to reduce street light on-time with a failed light source include reducing a street light threshold for the failed light source.

The instructions for the first smart sensor to reduce the street light operating time with the failed light source include delaying a street light illumination start time with the failed light source.

The processor executes upper computer instructions that, when executed by the processor, cause the processor to further determine an identified incident, a first smart sensor of the plurality of smart sensors identifies the incident as a weather incident identification affecting at least a subset of the plurality of street lights and captures data associated with the weather event for a first time period, a second smart sensor of the plurality of smart sensors captures data associated with the weather event during a second time period after the first time period identification, and determines an estimated path for the weather event based on a first position of the first smart sensor relative to a second position of the second smart sensor.

The processor executes upper computer instructions that, when executed by the processor, cause the processor to further identify a third intelligent sensor of the plurality of intelligent sensors in the estimated weather event path and instruct a third intelligent sensing device to output an alert regarding the weather event.

Comparing the current data signature to a plurality of known signatures comprises the acts of comparing a current data signature of a target smart sensor of the plurality of smart sensors to a light pole fatigue signature to generate an estimated time to failure of a light pole coupled to a street light device coupled to the target smart sensor and providing the estimated time to failure to a user.

When the intelligent street lamp is implemented, the street lamp is a device installed on roadside lighting, and each street lamp is provided with an intelligent sensor; each smart sensor includes an interface connector that conforms to the particular standard used by street light fixtures, enabling the smart sensor to be electromechanically coupled to the street light, typically on top of the street light. In this manner, the smart sensor is attached to or otherwise integrated into the street light device and can communicate information between the smart sensor device and the street light device, which information can include any one or more of high speed data, low speed data, power, digital signals, analog signals, differential signals, or other types of information; the smart sensors are preferably small cellular network devices, street light controllers, aerial smart sensor devices, and the like.

The intelligent sensor can capture light source temperature data and street lamp light power consumption data. The current data signature generated for this data may be a relationship between the light source temperature and the power consumption of the light source, which may provide an estimate of the light source efficiency; the product of the invention can autonomously identify the related street lamp fault condition, reasonably arrange the corresponding street lamp working time according to the fault condition, and enhance the illumination light source of the street lamp close to the fault street lamp so as to balance the light source near the fault street lamp as much as possible, and the light source is displayed to personnel managing the upper computer by the upper computer, thereby reminding people to overhaul in time and ensuring the driving safety of roads.

The present invention and its embodiments have been described above, but the description is not limitative, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (6)

1. The utility model provides an wisdom street lamp with trouble self-checking function which characterized in that: a respective street light device comprising a plurality of smart sensors coupled to a plurality of street lights, each smart sensor comprising a memory for storing data, a processor-based monitoring circuit, a processor for receiving data captured by one or more sensors and storing the received data in the memory, the processor for executing upper computer instructions; when executed, the processor aggregates stored data from the plurality of smart sensors and generates a current data signature, compares the current data signature to a plurality of known signatures, identifies a fault event affecting at least one of the plurality of street lights based on the comparison between the current data signature and the plurality of known signatures, and performs an operation according to the identified fault event; when executed by the processor, the upper computer instructs the processor to further determine which street light fixture has a faulty light source for the identified event, first identify a first smart sensor of the plurality of smart sensors coupled to the street light having the faulty light source, and then identify a second smart sensor of the plurality of smart sensors coupled to a second street light of the plurality of street lights and proximate to the first smart sensor, instruct the first smart sensor to decrease use of the street light having the faulty light source, and instruct the second smart sensor to increase use of the second street light operating light source.

2. The intelligent street lamp with the fault self-checking function as claimed in claim 1, wherein: the instructions for the first smart sensor to reduce street light on-time with a failed light source include reducing a street light threshold for the failed light source.

3. The intelligent street lamp with the fault self-checking function as claimed in claim 2, wherein: the instructions for the first smart sensor to reduce the street light operating time with the failed light source include delaying a street light illumination start time with the failed light source.

4. The intelligent street lamp with the fault self-checking function as claimed in claim 1, wherein: the processor executing upper computer instructions that, when executed by the processor, cause the processor to further determine an identified incident, a first smart sensor of the plurality of smart sensors identifying the incident as a weather incident identification affecting at least a subset of the plurality of street lights and capturing data associated with the weather event for a first time period, a second smart sensor of the plurality of smart sensors capturing data associated with the weather event during a second time period after the first time period identification; and determining an estimated path for the weather event based on the first position of the first smart sensor relative to the second position of the second smart sensor.

5. The intelligent street lamp with the fault self-checking function as claimed in claim 4, wherein: the processor executes upper computer instructions that, when executed by the processor, cause the processor to further identify a third intelligent sensor of the plurality of intelligent sensors in the estimated weather event path and instruct a third intelligent sensing device to output an alert regarding the weather event.

6. The intelligent street lamp with the fault self-checking function as claimed in claim 1, wherein: comparing the current data signature to a plurality of known signatures comprises the acts of comparing a current data signature of a target smart sensor of the plurality of smart sensors to a light pole fatigue signature to generate an estimated time to failure of a light pole coupled to a street light device coupled to the target smart sensor and providing the estimated time to failure to a user.