RU2249925C2 - Illumination control apparatus - Google Patents

Abstract

FIELD: municipal equipment of residential houses and industrial buildings, namely automatic systems for controlling electric parameters, namely apparatuses for automatic control of different-designation illuminating devices.

SUBSTANCE: apparatus includes primary pulse-type photo-converter with built-in photo detector forming output pulse-width modulated information signal; secondary converter including micro-controller, shaping amplifier, switch, display module, power unit, inductor, unit for controlling illumination, switching controller of power supply of mains. Secondary converter includes in addition real-time clock and standby power source. Primary pulse-type photo-converter is connected with secondary converter by means of two-wire line that is connected with inlet of shaping amplifier and first terminal of inductor at one side and outlet of primary pulse type converter at other side. Outlet of shaping amplifier is connected with first inlet of micro-controller whose second inlet is connected with switch. Third inlet of micro-controller is connected with outlet of real-time clock. First outlet of micro-controller is connected with first inlet of power unit. Second outlet of micro-controller is connected with inlet of display module. Inlet of illumination control module is connected with third outlet of micro-controller. AC supply mains is connected with second inlet of power unit whose first outlet is connected with second terminal of inductor. Second outlet of power unit is connected with inlet of standby power source whose outlet is connected with respective inlet of real time clock. Outlet of illumination control unit is connected with connected in parallel first inlets of N switching controllers of power of mains. AC mains is connected with second (connected in parallel) inlets of N switching controllers of power of mains. Connected in parallel outlets of said switching controllers through load (illuminating lamps) are connected with zero wire of AC mains.

EFFECT: enhanced operational reliability and safety of apparatus.

7 cl, 1 dwg

Description

The invention relates to the equipment of municipal engineering of residential buildings and industrial premises, and in particular to systems for the automatic control of electrical quantities, in particular to devices for the automatic control of lighting devices for various purposes.

A photorelay is known that contains a photocell included in a DC bridge, a comparator integrating an RC circuit, which excludes the possibility of switching a switching relay during short-term illumination or darkening of a photocell, a logic circuit and a key stage controlling a switching relay coil or triac [1]. This class of devices also includes commercially available photo relay brand FR (FR-1, FR-2, FR-7, etc.).

The disadvantages of these devices are: DC photocell supply; round-the-clock mode of operation of the device; lack of temperature correction of photocell readings; the small length of the cable connecting the photosensor and the block, in the case of a remote version of the photosensor; the combination of the photosensor and actuator functions in one node, which leads to the complication of installation and maintenance of the device and the need for wiring a high voltage power network (220 V, 50 Hz network) to the installation site, increased electrical hazard - lighting may turn on when replacing out of order light bulbs and injure a person; low reliability and short service life.

Known lighting controller POC [2], containing a photosensor, a control unit and executive units, and up to five executive units can be connected to the control output. In addition, the control unit has an input for connecting a broadcast network to switch the device to night lighting mode (from 24-00 to 6-00 the broadcast network is turned off and the absence of a signal is a command to switch executive units to low brightness mode).

The disadvantages of this device are: DC photocell supply; lack of temperature correction of photocell readings; 24-hour mode of operation of the photosensor (the mode contributes to the manifestation of such properties of the photosensor as aging - a slow change in light characteristics and fatigue); one lighting control channel, while in high-rise buildings there are halls and walkways where lighting is necessary in the daytime; when the photosensor fails, the lighting turns on and it is necessary to manually control it using the switch in manual mode, increased electrical hazard - the lighting may turn on when the failed lighting lamps are replaced and injure a person.

The closest technical solution to the proposed device is a lighting control unit [3] (prototype), comprising a primary converter containing an RC oscillator with a photocell turned on during the timing circuit; secondary converter, which includes: power supply unit; line control module; microcontroller; amplifier-driver with a characteristic of the “hysteresis" type; switch; display module and lighting control module; modules of floor lighting switches containing a smooth on-off circuit, a motion sensor and a timer - one per floor.

The disadvantages of this device are: round-the-clock operation of the primary converter; one lighting control channel, if we take into consideration one residential building, the device controls the lighting of one entrance; the absence of a second control channel for emergency lighting (in high-rise buildings there are halls and walkways where it is necessary to control the lighting during daylight hours), when the primary converter fails, the lighting is switched on and its manual control using a switch is necessary; increased electrical hazard - lighting may turn on at the time of replacement of failed lighting lamps and injure a person.

The technical result to which the invention is directed is to increase the service life and reliability; improving the comfort of use (remote control mode of the secondary converter and, accordingly, the network controllers, switches); electrical safety device; the exclusion of the possibility of connecting residents to the lighting of non-residential premises; energy saving.

A feature of the proposed lighting control device are:

two lighting control channels are used: the first channel, standard, controls the on and off lighting in the dark; the second channel controls the lighting of rooms where lighting is also required during daylight hours - elevator landing sites, the ground floor hall, corridors and areas with insufficient lighting during daylight hours. The control is carried out not by turning the lighting on and off, but by controlling the brightness of the illumination of the lighting lamps, network power controllers and switches are used with the mode of smooth on and off voltage and the amplitude of the voltage supplied to the lighting lamps is limited by the minimum acceptable value in accordance with GOST 13109-97; a real-time clock with a backup power source has been introduced that maintains operability after a power outage; a real-time clock is used to introduce a night-time shutdown of lighting lamps - only the second channel works in low-brightness mode; to turn off the primary converter (it works only during the period of twilight beginning and before complete darkening, and in the morning from the beginning of sunrise), which significantly increases the life of the photosensor; to control the lighting in emergency mode when the photosensor fails, the time for switching the lighting on and off is determined by calculation using the solar calendar;

in support of the concept of an intelligent building, a two-wire I ² C interface with an OCELOT / LEOPARD type controller or via a standard RS-485 interface with a personal computer was introduced. Additionally, using a two-wire I ² C interface, a remote display with a keyboard is connected at the time of repair work or programming system settings (for adjusting or initial setting the calendar and clock, scale factors and lighting control logic);

the functions of the circuit breaker are performed by low-voltage network controllers-switches (up to 12 V). They carry out the overcurrent protection functions of the lighting line; protection against unauthorized connection to lighting lines; protective shutdown devices (when the current difference in the phase and neutral wires is more than 3 mA, the output voltage is automatically turned off); smooth on and off voltage to the lighting lamps (in the case of application for lighting incandescent lamps); restrictions on the amplitude of the voltage supplied to the lighting lamps with the minimum acceptable value in accordance with GOST 13109-97;

The control light module incorporates a battery power supply, a three-position brightness control switch and a built-in lamp, consisting of white LEDs (emission wavelength of about 540 nm), the module provides seven degrees of brightness of the lamp, which is used for monitoring, pre-set using a light meter and setting (calibrating) the threshold for the operation of the lighting control device.

The specified technical result is achieved by the fact that in the lighting control device containing a primary pulsed photoconverter with a built-in photocell with an output interface information signal in the form of a pulse-width (PWM) signal, in one half-cycle containing information about the illumination, and in the other about the ambient temperature at the installation site of the primary pulsed photoconverter, the secondary converter, which includes a microcontroller; amplifier-driver (with the characteristic of the “hysteresis" type); switch; indication module; Power Supply; inductance; the lighting control module and the mains controller-commutator, in addition, a real-time clock and a backup power supply are introduced, the primary pulsed photoconverter connected to the secondary converter with a two-wire line through which phantom power is supplied to the primary pulsed photoconverter, the communication line is connected to the input of the amplifier-former and the first the inductance output on the one hand and the output of the primary pulse Converter, on the other; the first input of the microcontroller is connected to the output of the amplifier-former, the second input of the microcontroller is connected to the switch, the third input of the microcontroller is connected to the output of the real time clock, the first output of the microcontroller is connected to the first input of the power supply, the second output of the microcontroller is connected to the input of the display module, the input of the lighting control module connected to the third output of the microcontroller, the AC network is connected to the second input of the power supply, the first output of which is connected to the second output of the inductor In particular, the second output of the power supply is connected to the input of the backup power source, the output of which is connected to the corresponding input of the real-time clock, the output of the lighting control module is connected to the first inputs N of the mains controllers and switches connected in parallel, the AC network is connected to the second parallel inputs of N controllers-switches of the mains power supply, whose parallel outputs are connected through the load, the lighting lamps are connected to the neutral wire of the AC network.

The lighting control device may additionally comprise in the secondary converter a second lighting control module and N second network power controllers-switches, the fourth output of the microcontroller being connected to the input of the second lighting control module, the output of which is connected to the first N inputs of the second power supply controllers-switches parallel to the the AC network is connected to the second parallel-connected inputs of the second N controllers-switches of the mains supply, the output to Through the load, the lighting lamps are connected to the neutral wire of the AC network.

In addition, the lighting control device in the secondary converter may additionally comprise an interface module with an output 2-wire I ² C interface for communication with an OCELOT / LEOPARD type controller and / or with a standard RS-485 interface with an automated control system computer, the fifth output of the microcontroller being connected to input module interface.

Also, the lighting control device may further comprise an information board, and the information board is connected by a cable to the output of the interface secondary converter module.

The lighting control device may further comprise a control light module, mechanically connected to the primary flash photoconverter for checking and setting thresholds for lighting on and off.

In addition, the lighting control device in the secondary converter may further comprise an AC command transceiver, and AC power receivers are additionally introduced into the network controllers / switches, the sixth output of the microcontroller being connected to the input of the command transceiver, the output of which is connected to the third input of the unit nutrition.

In addition, the lighting control device may include a primary flash photoconverter with an output single-wire digital interface such as 1-WIRE BUS SYSTEM.

This embodiment of the lighting control device will allow us to solve the problem of creating a device of high reliability and electrical safety with an extended service life; increase the comfort of use; excluding the possibility of connecting residents to the lighting of non-residential premises; energy saving; improving the accuracy of measuring illumination and temperature.

Functional diagram of the lighting control device shown in the drawing.

The lighting control device comprises a primary pulse photoconverter 1, a secondary converter 2 connected by a two-wire communication line, and network controllers-switches 3, also connected by a two-wire line with a secondary converter 2. Phantom (simultaneously with the transmission of an information signal) power of the primary pulse photoconverter 1, the output of which is connected by a two-wire communication line with the input of the amplifier-former 6 and with the first output ind coaxiality L. Secondary converter 2 contains a microcontroller 4, a power supply 5, an inductance L, a driver amplifier 6 (with a hysteresis type characteristic), a switch 7, an indication module 8, a real-time clock 9, a backup power supply 10, a lighting control module 12. Control EL lighting lamps and perform the functions of residual current devices (RCD) controllers-switches of the mains power 3. The output of the amplifier-former 1 is connected to the first input of the microcontroller 4, the second input of which is connected to the switch 7, the third input of the microcontroller 4 is connected to the output of the real-time clock 9. The first output of the microcontroller is connected to the first input of the power supply 5, the second output of the microcontroller 4 is connected to the input of the display module 8. The input of the lighting control module 12 is connected to the third output of the microcontroller 4. AC network current is connected to the second input of the power supply 2, the first output of which is connected to the second output of the inductance L. The second output of the power supply 5 is connected to the input of the backup power source 10, the output of which is connected to the corresponding a real power supply input for the real-time clock 9. The output of the lighting control module 12 is connected to the first inputs N of the power supply controllers 3 connected in parallel, and the AC network is connected to the second parallel inputs of the N power supply controllers 3 of the controller 3, the outputs of which are connected in parallel through load, EL lighting lamps are connected to the neutral wire of the AC network.

The lighting control device additionally contains in the secondary converter 2 a second lighting control module 12 and N of the second network power controllers-switches 3. The fourth output of the microcontroller 4 is connected to the input of the second lighting control module 12, the output of which is connected to the first inputs of the second N controllers-switches in parallel power supply 3. The AC network is connected to the second parallel-connected inputs of the second N controllers-switches of the power supply 3, the outputs of which x through the load, the EL lighting lamps are connected to the AC neutral wire.

In addition, the lighting control device in the secondary converter 2 additionally contains an interface module 11 with an output two-wire I ² C interface for communication with an OCELOT / LEOPARD type controller and / or with a standard RS-485 interface with a computer of an automated control system. The fifth output of the microcontroller 4 is connected to the input of the interface module 11.

The lighting control device also contains an information board 13, which is equipped with a group of devices. When connected to the lighting control device, the information board 11 is connected by a cable to the output of the interface module 11 of the secondary converter 2.

The lighting control device further comprises a control light module 14, mechanically connected to the primary flash photoconverter 1 for checking and setting thresholds for lighting on and off (calibration). The control light module 14 has seven light installations checked by a light meter for carrying out operational control and tuning the characteristics of the primary pulse photoconverter 1.

Additionally, the lighting control device comprises, in the secondary converter 2, a command transceiver via an alternating current network 13, and the network power controllers-switches further comprise receiving devices. The sixth output of the microcontroller 4 is connected to the input of the command transceiver via an alternating current network 13, the output of which is connected to the third input of the power supply 5. The guaranteed radius of operation of the command transceiver 13 under industrial noise conditions, i.e. under urban network loads, it is about 200 m. The command transceiver is controlled via alternating current network 13 also with console street lighting.

In addition, the lighting control device includes a primary flash photoconverter 1 with an output single-wire digital interface type 1-WIRE BUS SYSTEM.

The microcontroller 4, which is part of the secondary converter, is based on the AVR-8-Bit-RISC microcontroller AT90S2313, the controllers and switches of the mains power 3 are made on the KR1182PM1 and KR1182CA1 microcircuits manufactured by the Scientific and Technical Center SIT in Bryansk. Real-time clock 9 is made on a chip DS 1307 from Dallas Inc. The transceiver via AC 13 is based on the KR1446XK1 microcircuit manufactured by Angstrem OJSC. The programming of the microcontroller 4 is carried out during the assembly of the intercom; a mode of in-circuit programming of the microcontroller 4 is also provided for when changing the configuration or upgrading the device — expanding functions, for example, as a programmable time relay.

The lighting control device operates as follows.

The information signal from the primary Converter 1 is fed to the input of the amplifier-driver, is normalized, and from its output the signal is fed to the first input of the microcontroller 4, which is the input of the first built-in timer and / or input, which receives an information signal proportional to the temperature at the installation site of the primary pulsed photoconverter 1 and illumination. Microcontroller 4 with a cycle of one second measures the duration of the signals received at its input. In the read-only memory of the microcontroller 4, a table of correspondence of the pulse duration of the signal of the primary pulse photoconverter 1 containing information about the temperature, the ambient temperature is stored. Next, the microcontroller 4 calculates the true value of the illumination, enters the correction of the readings in accordance with the temperature at the installation site of the primary pulse photoconverter 1, transcribes the value of the previous measurement cycle to the second register of temporary storage of data, and writes the converted data of the current measurement to the first register. The calculated difference between the current and previous illumination values is entered in the third register. The resulting difference value is compared with the average interval of changes in illumination stored in the memory of the microcontroller 4, and if the value is outside the permissible limit, the current measurement data is ignored, and the microcontroller 4 conducts a repeated measurement cycle. The microcontroller 4 when exceeding the differential value of the lighting conducts up to ten repeated measurement cycles, with a measurement delay of up to ten seconds, after which the value is considered true. Compensation of the systematic measurement error occurs using tables and correction (calibration) factors. The code of the current lighting measurement is displayed for visual control on the display module 8. Microcontroller 4 reads the binary code of the threshold for turning on the lighting from the output of switch 2, if the interface module is not installed, and if installed, from the data temporary storage register, compares the code with the calculated value and if it is exceeded threshold generates an enable signal for lighting on from its third output, fed to the input of the lighting control module 12, which issues a command to the network controllers-switches 3 n and the inclusion of voltage on the EL lighting lamps, smoothly turns on the voltage on N parallel EL lighting lamps. The threshold for turning off the lighting is calculated by the microcontroller 4 by subtracting from the code 7 received from the switch 7 a constant value of about five percent of the threshold value. The value of the hysteresis can be changed by the user using the information panel by entering other values of the correction factors. When the illumination decreases below the calculated threshold, the command from the third output of the microcontroller 4 illuminates smoothly. A digital comparator function with a “hysteresis” characteristic has been implemented, with temperature correction of the photocell readings, with protection from short-term (up to two minutes) switching of lighting, for example, due to short-term illumination of the photosensor by the headlights of a passing car or short-term dimming of the photocell of the primary flash photoconverter 1. The operating time of the primary pulse photoconverter is calculated by the microcontroller 4 according to the calendar method, according to the readings of real time clocks Yeni 9, taking into account the time of sunrise and sunset. The primary installation of real-time clock 9 is made at the manufacturer at the time of commissioning. Microcontroller 4 uses the signal from its first output to the first input of the power supply by turning on the voltage to the first output of power supply 5 and turns on the primary pulsed photoconverter 1 at a predetermined time. Additionally, the time for lighting to be turned on and off can be controlled by microcontroller 4 in the case of a summer simulation program daylight in the winter, when using a lighting control device in an incubator, greenhouses, etc. The storage time of the operation of the real-time clock 9 from the backup power source 10 is from three months, when using an ionistor (large-capacity capacitor with a double electric layer), up to ten years, when using a lithium cell. In emergency mode, in the absence of a signal from the primary pulse photoconverter 1, the lighting control device operates using the calendar method, taking into account the time of sunset and sunrise. When installing the second lighting control module and the second N controllers-switches of the mains supply in places where lighting is necessary in the daytime, the microcontroller 4 controls the signal brightness of the lamps using its second lighting control module from the fourth output. The microcontroller 4 calculates the threshold for changing the brightness of additional illumination lamps using the correction to the main value stored in the temporary data storage register of the microcontroller 4.

During the initial installation or in the process of monitoring the operation of the lighting control device, the response threshold of the latter is set using the light control module 14. It is mechanically mounted on the primary flash photoconverter and the necessary brightness mode of the built-in LEDs is switched on (emission range of about 540 nm). According to the indications of the display module 8 and the set threshold, the switch 7 judges the installation error and, if necessary, makes the appropriate adjustment to the setting of the threshold. When using the light control module, there is no need at each object to wait for the twilight time to set the required threshold for turning on and off the lighting.

If it is impossible or difficult to lay the lines connecting the controllers-switches of the power supply 3 to the secondary converter 2, the lighting control device is additionally equipped with a command transceiver via AC 13. In this case, the signal from the sixth output of the microcontroller 4 is fed to the input of the command transceiver via AC 13, from the output of which through the power supply 2 enters the AC network. The guaranteed range of operation of the command transceiver over the AC network 13 in a city is about 200 m. In this case, the control device switches include a receiving device over the AC network, which receives commands, decodes and transfers for execution, i.e. enables or disables lighting in case of identification of commands.

When connecting a lighting control device to centralized controllers using an interface module with an output two-wire I ² C interface for communication with an OCELOT / LEOPARD type controller and / or with a standard RS-485 interface for communicating with an automated control system computer, the latter can directly with the highest priority give a command to turn on and off the lighting, the lighting control device for identification has its own seven-bit address and, upon receipt of an external request, returns to controllers a code proportional to the measured and corrected brightness of the light, a value from 0 to 255, depending on the illumination, and the more light falls on the photoresistor, the lower the sensor returns, the second byte the device returns a code proportional to the ambient temperature at the installation site primary pulsed photoconverter 1, moreover, the code 00h is accepted for 0 ° С, the minus temperature is transmitted in an additional code, for example -25 ° С corresponds to the code 11100111b (E7h), and the temperature is +25 ° C corresponds to code 00011001 (19h).

Sources of information used in the description of the invention:

1. FRG patent No. 3443406, class H 01 H 47/24, 1984

2. Technical passport for the regulator of lighting POC. World Wide Web http://www.orel.ru/straj.

3. Application for a patent of the Russian Federation No. 2001125028, IPC 7 H 01 H 47/24, 2001. Decision on the grant of a patent of the Russian Federation dated January 30, 2003.

Claims (7)

1. A lighting control device comprising a primary pulse photoconverter with a built-in photocell, with an output pulse-width information signal, a secondary converter, which includes: a microcontroller; amplifier driver; switch; indication module; Power Supply; inductance; a lighting control device and a network power controller-switch, characterized in that the secondary converter is additionally provided with a real-time clock and a backup power source, the primary pulse photoconverter connected to the secondary converter with a two-wire line, the communication line connected to the input of the amplifier-former and the first output of the inductance on the one hand and with the output of the primary pulse converter on the other, the output of the amplifier-former is connected to the first input of the microcon a controller, the second input of which is connected to the switch, the third input of the microcontroller is connected to the output of the real-time clock, the first output of the microcontroller is connected to the first input of the power supply, the second output of the microcontroller is connected to the input of the display module, the input of the lighting control module is connected to the third output of the microcontroller, the AC network current is connected to the second input of the power supply, the first output of which is connected to the second output of the inductance, the second output of the power supply is connected to the input of the backup source a power supply, the output of which is connected to the corresponding input of the real-time clock power supply, the output of the lighting control module is connected to the first inputs of the N controllers of the mains power supply connected in parallel, the AC network is connected to the second, parallel connected inputs of the N controllers of the mains power supply, in parallel the connected outputs of which through the load, the lighting lamps, are connected to the neutral wire of the AC network. 2. The lighting control device according to claim 1, characterized in that N second controllers of the mains power supply are additionally introduced into it and a second lighting control module is introduced into the secondary converter, the fourth output of the microcontroller connected to the input of the second lighting control module, the output of which is connected with the first inputs of the second N controllers of the mains power supply connected in parallel, the AC network is connected to the second, parallelly connected inputs of the second N controllers utatorov mains supply, the output of which through the load, lamp lighting, connected with the neutral conductor AC. 3. The lighting control device according to claim 1 or 2, characterized in that it is additionally inserted into the secondary converter into an interface module with an output two-wire I ² C interface for communication with an OCELOT / LEOPARD type controller and / or with a standard RS-485 the computer interface of the automated control system, and the fifth output of the microcontroller is connected to the input of the interface module. 4. The lighting control device according to claim 3, characterized in that an information board is additionally inserted into it, wherein the information board is connected by a cable to the output of the interface secondary converter module. 5. The lighting control device according to claim 1, or 2, or 3, or 4, characterized in that it additionally includes a control light module, mechanically connected to the primary flash photoconverter, for monitoring and setting thresholds for turning on and off the lighting. 6. The lighting control device according to claim 1, or 2, or 3, or 4, or 5, characterized in that it is additionally introduced into the secondary converter, the command transceiver via an alternating current network, and additionally into the network controllers-switches receiving devices are introduced via an alternating current network, and the sixth output of the microcontroller is connected to the input of the command transceiver, the output of which is connected to the third input of the power supply. 7. The lighting control device according to claim 1, or 2, or 3, or 4, or 5, or 6, characterized in that in it, in the primary pulse photoconverter, the interface information signal is made in the form of a single-wire digital interface.