RU205781U1 - Lighting control device - Google Patents

Abstract

The utility model relates to the field of electrical engineering and automation and can be used in devices for automatic control and management of street lighting in the form of a device located on street lighting fixtures and made with the possibility of remote transmission of commands to it using standard protocols 1-10 or DALI. , which consists in expanding the arsenal of technical means for remote monitoring and control of the luminaire, providing reliable implementation of complex programmable control algorithms, is achieved in a device designed to be mounted on a luminaire in the form of a cylindrical moisture-proof housing with a spherical upper part and a lower part with a NEMA plug-pin contact , moreover, a power supply and control interface board is introduced into it, installed in the lower part of the housing and made with the possibility of being connected to the NEMA plug-pin contact, a communication board installed in the upper part of the housing a mustache, and a processor board installed in the middle part of the case and connected to the power supply and control interfaces board and to the communication board. 2 ill.

Description

The utility model relates to the field of electrical engineering and automation and can be used in devices for automatic control and management of street lighting in the form of a device located on street lighting fixtures and made with the possibility of remote transmission of commands to it using standard protocols 1-10 or DALI.

There is a known device for controlling a LED lamp via a GSM channel [https://www.sundrax.ru/products/street/individual/gsm+control+unit/], designed to be placed on a lamp and its addressable control via a GSM channel with the possibility of combining them into groups, as well as use the dimming function, operational monitoring of the performance of the implementation of various lighting scenarios, taking into account the time of day, outdoor activity, and the level of natural light.

A device for individual control of a lamp is also known. [https://unilight.ru/oborudovanie/modul-upravleniya-osveshheniem/], which has an all-weather housing with built-in protection against pressure fluctuations caused by temperature changes and provides support for up to 16 independently controlled lighting modules, providing functions and capabilities of independent wireless protocols data transfer, data transfer to two unconnected servers, backup of data transfer via the second communication channel in case of any type of connection failure, use of any combination of LoRaWAN + 2G / 3G / NB-IoT connection types, automatic geolocation via GPS and GLONASS systems, interaction with built-in sensors of humidity, temperature, illumination and protection of data transmission using multiple coding.

The closest in technical essence to the proposed one is a luminaire control device via a wireless GSM network [https://www.sundrax.ru/products/street/individual/ gsm + control + unit /], installed on the luminaire and remotely connected to the software server , which is made in the form of a cylindrical moisture-proof housing with a spherical upper part and a lower housing with a NEMA plug-pin contact, while the housing has a built-in light sensor, a built-in GPS / GLONASS receiver, a built-in relay for disconnecting the load, automatic positioning and a terminal -input for the motion sensor.

The disadvantage of the devices is the relatively narrow functionality, since, although the device allows monitoring the state of the luminaire and making it remotely on and off, as well as similar manipulations on the signal from the motion sensor, it does not provide a more complex control algorithm that requires the use of a processor and communication means and interfaces of management with their reliable power supply. All this narrows the arsenal of technical means that can be used as lighting control devices.

The task of the utility model is to create a lighting control device, which provides remote control and control of the luminaire according to complex algorithms, is made in the form of a cylindrical moisture-proof housing with a spherical upper part and a lower housing part with a NEMA plug-pin contact, while a built-in light sensor is installed in the housing. , built-in GPS / GLONASS receiver, built-in relay for disconnecting the load, automatic positioning means and an input terminal for the motion sensor.

The required technical result consists in expanding the arsenal of technical means for remote monitoring and control of the luminaire, providing reliable implementation of complex programmable control algorithms.

The problem is solved, and the required technical result is achieved by the fact that, in a device installed on a lamp and remotely connected to a software server, which is made in the form of a cylindrical moisture-proof housing with a spherical upper part and a lower housing part with a NEMA plug-pin contact, when In this case, a built-in GPS / GLONASS with automatic positioning means is installed in the case, according to the utility model, a power supply and control interface board is introduced, installed in the lower part of the case and connected to the NEMA plug-pin contact, a communication board installed in the upper part of the case, and a board processor installed in the middle part of the case and connected to the power supply and control interfaces board and to the communication board.

The drawing shows:

in fig. 1 - lighting control device with an example of its installation in a luminaire;

in fig. 2 - housing lighting control device with NEMA male plug.

The lighting control device is made in the form of a cylindrical moisture-proof housing 1 with a spherical upper part 2 and a lower part 3 of the housing with a NEMA plug-pin contact with the possibility of mounting on a luminaire 4.

In case 1, a power supply and control interface board 5 is installed, installed in the lower part of the case 3 and connected to a NEMA male plug, a communication board 6, installed in the upper part of the case, and a processor board 7, installed in the middle part of the case and connected to the board 5 power supply and control interfaces and 6 communication board.

The lighting control device works as follows.

The device receives commands from a lighting control system of a higher level, for example, an urban area, which provides automatic / automated centralized control of street lighting at enterprises of urban electrical networks and other facilities using a software and hardware complex that includes the proposed lighting control device.

The lighting control system can be integrated into the existing ecosystem of settlements to interact with other infrastructural elements, for example, with a system for automatic accounting of production (receipt) and accounting for electricity consumption.

The device receives commands from a higher-level lighting control system via a wireless information transmission channel, stores in its memory the schedules and algorithms of the lamp operation and, in accordance with the programmed program and the received commands, controls the lighting lamp.

Additional advantages of the device are:

- placement in a standard NEMA-type enclosure;

- execution in the form of a modular structure;

- boards have the same external dimensions and are located one above the other, which ensures their easy replacement and ensures high maintainability.

Thus, the device ensures the achievement of the required technical result, which consists in expanding the arsenal of technical means for remote monitoring and control of the luminaire, providing reliable implementation of complex programmable control algorithms.

Claims (1)

A lighting control device configured to be mounted on a luminaire in the form of a cylindrical moisture-proof housing with a spherical upper part and a lower part with a NEMA plug-pin contact, characterized in that it includes a power supply and control interface board installed in the lower part of the housing and made with optionally connected to a NEMA male plug, a communication board installed in the upper part of the housing, and a processor board installed in the middle part of the housing and connected to a power supply and control interfaces board and a communication board.

Images