RU95448U1 - INTERACTIVE ENERGY-SAVING LIGHTING SYSTEM - Google Patents

Abstract

1. Interactive energy-saving lighting system, which includes an uninterruptible power supply with an AC voltage converter to the supply voltage of lighting fixtures, a lighting line in the form of a set of lighting fixtures and a lighting intensity control circuit for lighting fixtures, as well as a microcontroller, characterized in that the lighting intensity control circuit of lighting devices is made common for the entire lighting line and contains a microcontroller located between the output of the uninterruptible power supply and the input of the lighting line, equipped with an analog-to-digital converter, to the input of which a photoresistive sensor is connected, two universal synchronous-asynchronous transceivers and a built-in GSM / GPRS-module connected with one of the synchronous-asynchronous transceivers, as well as a microcontroller control unit, the output of which is connected to the microcontroller input, while the microcontroller is connected to the lighting line by means of a block and control of the lighting line and a detector of the characteristics of the lighting line, providing feedback of the lighting line with the analog-to-digital converter, while the lighting line includes semiconductor lighting devices. ! 2. Interactive energy-saving lighting system according to claim 1, characterized in that it includes an indication unit, the input of which is connected to the output of the microcontroller. ! 3. An interactive energy-saving lighting system according to claim 1, characterized in that it includes an external EEPROM memory connected via a software-organized internal clipboard to the microcontroller, as well as a converter unit.

Description

The utility model relates to energy-saving lighting systems and can be used to illuminate the entrances and corridors of residential buildings, the interior of industrial, office and commercial buildings.

A known lighting system (US Pat. RF No. 2369990, publ. 2009.10.10), including a control device that allows using the central control unit to control the on and off of lighting devices and provides the user with the ability to adjust the brightness of the lighting, as well as containing decentralized lamp control devices that can be operated in various operating modes, while the selection and installation of the operating mode of the lamp control device is carried out by the Central control unit. The disadvantages of the known lighting system include the lack of energy-saving control units and energy-saving operation algorithms, its limited functionality associated with the lack of continuous monitoring of lighting lines and the ability to alert about malfunctions, as well as the lack of an autonomous power source.

The closest in technical essence to the claimed technical solution is an energy and resource-saving DC lighting system (US Pat. No. 80087 for utility model, published 2009.01.20), which includes an uninterruptible power supply, which includes an AC voltage converter DC voltage and an autonomous power source, lamps containing a lighting device connected to an uninterruptible power supply through an AC voltage converter in n the power supply of the lighting device, and the control circuit of the aforementioned voltage converter, which allows you to adjust the power of the lighting device and provides an energy-saving mode of operation of the lighting line, which is a combination of lighting devices, and may also include modems and a microcontroller to provide centralized control of all the lights of the lighting system.

The disadvantages of the known lighting system are the lack of the ability to control the intensity of lighting in automatic mode, the insufficiently high level of energy saving, and the inability to diagnose malfunctions of the lighting system and notify technical personnel about them.

The objective of the utility model is the creation of a highly economical interactive energy-saving lighting system with automatic lighting control, as well as the ability to diagnose faults and notify technical personnel about them.

The technical result of the utility model is to provide the ability to control the intensity of lighting in automatic mode, the ability to diagnose malfunctions of the lighting system and send appropriate messages to technical personnel while increasing energy saving and increasing the life of the lighting devices.

The indicated technical result is achieved by an interactive energy-saving lighting system, including an uninterruptible power supply with a converter for AC voltage to the lighting voltage of the lighting devices, a lighting line in the form of a set of lighting devices and a control circuit for the luminous intensity of the lighting devices, as well as a microcontroller, in which, unlike known, the control circuit of the intensity of the luminescence of lighting devices made common to the entire line of lighting and A microcontroller located between the output of the uninterruptible power supply and the input of the lighting line is equipped with an analog-to-digital converter, to the input of which a photoresistive sensor is connected, two universal synchronous-asynchronous transceivers and an integrated GSM / GPRS-module connected to one of the synchronously-asynchronous transceivers, and also the control unit of the microcontroller, the output of which is connected to the input of the microcontroller, while the microcontroller is connected to the lighting line by means of the control unit Nia lighting and light detector line performance, providing feedback lighting line with analog-to-digital converter, and the lighting line includes semiconductor lighting.

To provide text-digital information reflecting the operation of the lighting line, the proposed lighting system contains an indication unit, the input of which is connected to the output of the microcontroller.

To preserve the characteristics of the operation of the lighting line with subsequent recording in the computer's memory, the proposed lighting system includes an external EEPROM memory connected via a programmatically organized internal clipboard to the microcontroller, as well as a signal level conversion unit of the RS232 protocol whose input / output is connected to the output / input of one of the blocks universal synchronous asynchronous transceiver.

To ensure that the necessary lighting lines are automatically turned on / off when a person is / is not in the room, the proposed lighting system includes one or more motion sensors connected between the line characteristics detector and the lighting lines. It is possible to install motion sensors in front of each lighting fixture.

The proposed interactive energy-saving lighting system is schematically depicted in the drawing.

The proposed lighting system contains an uninterruptible power supply 1, connected to an alternating current network, a control circuit 2 for the operation of lighting devices, which is a microcontroller control circuit, and also a lighting line 3, including lighting devices.

Uninterruptible power supply 1 includes a network converter 4, the input of which is connected to 220 V AC through a single-phase electric meter, and the output to the main rectifier 5, the output of which is connected to the input of voltage regulator 6. To ensure uninterrupted power, the output of voltage stabilizer 6 is connected to the input of the backup power supply 7, the outputs of which are connected to the battery 8 and the DC / DC converter 9. The output of the voltage stabilizer 6 is connected to the control unit 10 detecting illumination line, part of the microcontroller control circuit 2, and the output DC voltage converter 9 is connected to the network entry control circuit microcontroller 2.

The microcontroller control circuit 2 includes a microcontroller 11 equipped with an analog-to-digital conversion (ADC) unit 12 and two universal synchronous-asynchronous transceivers (USAPP 1 - unit 13 and USAPP 2 - unit 14), as well as a control unit 15, the output of which is connected to the input microcontroller port 11.

In addition, the microcontroller control circuit 2 includes an indication unit 16, the input of which is connected to the output of the port of the microcontroller 11, as well as a signal level conversion unit 17 of the RS232 protocol whose input / output is connected to the output / input of the USAPP 1 unit 13.

The microcontroller control circuit 2 includes a GSM / GPRS module 18, the input / output of which is connected to the output / input of unit 14 of USAPP 2; block 10 control lighting lines, the input of which is connected to the output port of the microcontroller 11, and the output to the input of the detector characteristics of the lines 19, while the output of the latter is connected to the block 12 of the ADC, as well as in series or in parallel, or in series-parallel to the input of motion sensors 20 (20a, 20b, 20c, 20n) associated with the lighting line 3. Motion sensors 20 can be made in the form of infrared, radio frequency, ultrasonic or sound sensors. It is possible to install motion sensors in front of each lighting fixture. It is also possible to connect lighting lines without motion sensors.

The output of the motion sensors 20 is connected to the input of the lighting line 3, which includes a set of semiconductor lighting devices 21 (21a, 21b, 21n) connected in series, in parallel or in series-in parallel.

As a semiconductor lighting device, the proposed lighting system contains InGaN-based semiconductor white light sources with achieved light output of 100-180 Lm / W and color temperature of 6000-8000 K, the efficiency of which is 2.5-4.5 times higher than that of modern fluorescent lamps. The use of these semiconductor light sources will reduce lighting energy consumption by 60-78% compared with fluorescent lamps.

The output of the photoconductive sensor 22 is connected to the input of the ADC block 12.

The device operates as follows.

When connecting uninterruptible power supply 1 through a single-phase electric meter to an alternating current network, the microcontroller control circuit 2 receives the supply voltage from the DC / DC converter 9, after which the microcontroller 11 starts to generate pulsed signals with a frequency of 0.1-1000 kHz and a voltage of 5 V, received on the block 10 control line lighting 3.

Uninterruptible power supply 1, including a backup power supply 7, provides continuous lighting (up to 24 hours) in case of power outages. In this case, temporary shutdown or change in the intensity of the luminescence of lighting devices as a result of voltage drops or its complete shutdown in the main network is excluded.

As a result of the passage of the specified pulse signal through block 10, its output voltage rises to 27 V. After that, the signal passes through the detector 19 of the characteristics of the lighting line, then through the motion sensor 20 (if available in the lighting system) and enters the lighting devices 21 of the lighting line 3 .

In the process of the proposed interactive energy-saving lighting system, the microcontroller control circuit 2 through the built-in ADC 12 constantly polls the photoresistive sensor 22, as well as the line characteristics detector 19. As a result, when the input voltage supplied to the ADC 12 from the photoresistive sensor 22 changes, the duty cycle of the generated signal entering the block 10 control lines of lighting, and thereby provides a smooth change in the intensity of illumination of lighting devices, in odyaschih in lighting line.

Changing the input voltage to the lighting line coming from the detector of the characteristics of the lines 19, provides the disconnection / inclusion of these lines.

A change in the mentioned input voltage can occur, in particular, as a result of a short circuit, a break in one or more lighting lines, failure of one or more lighting devices, or the connection of an additional load. In the event of one or more of these events, the microcontroller 11 generates a corresponding message and transmits it through block 13 (USAPP 1) to the GSM / GPRS module 18, which, in turn, transmits the generated message to the maintenance personnel, for example, in the form of automatically sent to a mobile phone, SMS messages or messages to a personal computer (not shown in the drawing) or activates a light and sound alarm, notifying about the incident. The presence of a GSM / GPRS module allows you to instantly diagnose the system and send alarm messages to technical personnel (electrics, security, equipment, etc.) also in the event of unlawful actions by third parties (wire breakage, connecting an additional load).

If a failure occurs in any lighting device in the line (other devices are not disconnected) or other malfunctions, the input voltage is corrected.

After troubleshooting, the lighting lines are automatically turned on.

Automatic on / off, as well as a change in the intensity of lighting depending on the natural light coming in through the windows of the room, provides energy savings and an increase in the life of lighting devices up to 50%.

The microcontroller control circuit 2 by means of the control unit 15 provides an adjustment of the operating mode of the lighting line 21 by increasing or decreasing the duty cycle of the generated signal. Thus, in contrast to the known lighting system, in which the luminous intensity of the lighting fixtures varies depending on the power consumption (current strength), in the proposed lighting system, the indicated luminous intensity is determined by the duty cycle of the generated signal, while providing less overheating of the semiconductor crystals of the lighting devices and an increase in the term their service.

The semiconductor lighting devices included in the lighting line change the luminosity (“flicker”) with a frequency of 0.1 to 1000 kHz. The indicated frequency of “flicker” is safe for human vision, while the human eye is not able to notice a change in the intensity of the glow. The spent electricity almost completely goes into light with a high efficiency in the absence of losses due to thermal conversion.

The control unit 15 also serves to assign each lighting line an individual address, since the proposed lighting system may include from 1 to 16 lighting lines.

So, thanks to the presence of a GSM / GPRS module 18 and an ADC built into the microcontroller, with a photoresistive sensor connected to it, the microcontroller control circuit 2 allows you to control the light intensity in automatic mode, depending on natural light.

All information regarding the characteristics of the operation of the lighting lines (current consumption, supply voltage, line address, line fault and fault characteristic) is displayed in text-digital form using the display unit 16 of the microcontroller control circuit 2.

All characteristics of the operation of the lighting line are continuously stored in the event log of the external memory EEPROM (block 23). All stored information is transferred from the external EEPROM memory to a programmatically organized internal clipboard of unit 14 (USAPP 2) integrated in the microcontroller, after which the transmitted data through the signal level conversion unit 17 of the RS232 protocol is transferred to a personal computer. If necessary, all information can be stored in the memory of a personal computer.

Motion sensors 20, connected between the detector of the characteristics of the lighting lines 19 and the lighting line 3, provide automatic switching on / off of the lighting line when a person is (absent) in the room. As motion sensors can serve as infrared radiation sensors, radio frequency, ultrasonic or sound sensors.

Thus, as a result, the proposed energy-saving interactive lighting system saves from 90 to 98% of electricity, that is, 40-48% more than the known lighting system, while the life of semiconductor lamps can be from 11.5 to 25 years, which is also a significant savings.

Claims (4)

1. Interactive energy-saving lighting system, including an uninterruptible power supply with a converter for AC voltage to the lighting voltage of the lighting fixtures, a lighting line in the form of a combination of lighting fixtures and a lighting intensity control circuit for lighting devices, as well as a microcontroller, characterized in that the lighting intensity control circuit lighting devices made common to the entire lighting line and contains located between the output of the uninterrupted source the power supply and the input of the lighting line, a microcontroller equipped with an analog-to-digital converter, to the input of which a photoresistive sensor is connected, two universal synchronous-asynchronous transceivers and an integrated GSM / GPRS-module connected to one of the synchronously-asynchronous transceivers, as well as a microcontroller control unit, output which is connected to the input of the microcontroller, while the microcontroller is connected to the lighting line through the control unit of the lighting line and the detector characteristics of the lighting line I, providing feedback of the lighting line with an analog-to-digital converter, while the lighting line includes semiconductor lighting devices. 2. The interactive energy-saving lighting system according to claim 1, characterized in that it includes an indication unit, the input of which is connected to the output of the microcontroller. 3. The interactive energy-saving lighting system according to claim 1, characterized in that it includes an external EEPROM memory connected through a program-organized internal clipboard to the microcontroller, as well as a signal level conversion unit of the RS232 protocol, the input / output of which is connected to the output / input of one from the blocks of a universal synchronous-asynchronous transceiver. 4. The interactive energy-saving lighting system according to claim 1, characterized in that it includes one or more motion sensors connected between the line characteristics detector and the lighting lines.