RU92552U1 - VOLTAGE REGULATOR FOR LIGHTING SYSTEMS - Google Patents

Abstract

1. The voltage regulator for lighting systems, which includes an adjustment unit, as well as a control unit, characterized in that the adjustment unit contains an autotransformer and voltage adjustment switches connected to its taps, and the control unit contains a microcontroller, the inputs of which are connected to at least a sensor input voltage, output voltage sensor, load current sensor, and the outputs are connected at least to the control inputs of the voltage adjustment switches, providing a signal m of the microcontroller, switching the taps of the autotransformer to obtain the calculated output voltage at the load. ! 2. The controller according to claim 1, characterized in that it also contains an ambient light sensor connected to one of the inputs of the microcontroller, and a device for adjusting the brightness of lighting devices with a voltage of 0-10 V DC connected to one of the outputs of the microcontroller. ! 3. The controller according to any one of claims 1 or 2, characterized in that one of the outputs of the microcontroller is connected to a backup cooling fan, and one of the inputs is connected to a thermostat sensor. ! 4. The controller according to any one of claims 1 or 2, characterized in that the outputs of the microcontroller are connected to a device for displaying information about the status of the controller. ! 5. The controller according to any one of claims 1 or 2, characterized in that the outputs of the microcontroller are connected to a remote control device.

Description

The utility model relates to electrical engineering, namely to regulators and stabilizers of alternating current voltage, and is intended for use in power supply systems of outdoor lighting systems for regulating and stabilizing a single-phase voltage of an alternating current network of 220 V, 50 Hz.

A voltage regulator is known, comprising a transformer with a primary winding having two clamps and a secondary winding having three clamps, to which compensating active-reactance resistances and counter-activated controlled valves are connected, a valve control device is connected to the side of the energy source (Application JP48-40932, publication 1973, 04. XII, No. 4-1024.) The voltage at the load is controlled by controlling the opening angle of the counter-parallel connected controlled valves. This voltage regulator has large dimensions, since the load is supplied by means of a transformer, in addition, the voltage regulator creates high interference due to switching by controlled load current valves.

Known ferroresonant voltage stabilizer (Electrical stabilizers, BSE, M. 1976, p. 388.), Which has a network coil and filter coil, autotransformer and capacitor. This ferroresonant stabilizer has large dimensions, since energy is supplied to the consumer from the ferroresonant autotransformer shunt.

Known adjustable AC-to-AC converter (Copyright Certificate SU No. 1697061, G05F 1/30, Н02М 5/12, Bull. No. 45 07.12.91.). This device contains matching and booster transformers and unidirectional controlled keys connected to the primary winding of the matching transformer, the secondary winding of which is the source of the output voltage. The primary winding of the booster transformer contains two identical counter-connected windings, and the secondary winding of the booster transformer is connected in series to the output voltage. The device is complex, has large dimensions and weight in view of the presence of two transformers, one of which provides power to the load and the boost transformer with the same primary windings and low efficiency, and also controls the voltage only when the input voltage changes upwards, which does not allow to achieve technical the result of the proposed utility model. This device is taken as a prototype.

The main objective of this utility model was the creation of a new voltage regulator, which can be used for lighting systems, and would be characterized by smaller dimensions, provide a higher efficiency compared to the prototype and the ability to regulate voltage, both up and down.

Another objective of the utility model was the creation of a voltage regulator that provides control of external lighting systems based on natural light and a calendar of use.

The main task is solved in the voltage regulator for lighting systems, which includes an adjustment unit, as well as a control unit, in which, according to a utility model, the adjustment unit contains an autotransformer and voltage regulation switches connected to its taps, and the control unit contains a microcontroller, the inputs of which are connected via at least with an input voltage sensor, an output voltage sensor, a load current sensor, and the outputs are connected to at least the control inputs of the adjustment switches voltage, providing the signal of the microcontroller switching the taps of the autotransformer to obtain the calculated output voltage at the load.

The proposed controller allows you to increase efficiency by reducing the number of current transformers, increase speed, to obtain sufficient accuracy of the controller with a minimum number of keys in the switches. Using the controller control unit containing a microcontroller improves the reliability by significantly reducing the number of discrete electronic elements and processing a significant number of emergency situations, the measurement accuracy and the amount of displayed information are also increased, and the cost of the controller is reduced. Due to the interconnection of the microcontroller with the voltage and load current sensors, as well as the connection of the outputs of the microcontroller with the control inputs of the voltage regulation switches, the claimed device uses a combined method of regulating the output voltage at the input and output of the autotransformer, which provides an efficiency of up to 97% and the possibility of voltage regulation, as in big and smaller side.

In a preferred case, the controller also contains an ambient light sensor connected to one of the inputs of the microcontroller, and a device for adjusting the brightness of the lighting devices with a voltage of 0-10 V DC connected to one of the outputs of the microcontroller. The connection of the microcontroller with the light sensor and the device for adjusting the brightness of lighting devices allows, taking into account the previously described set of features, to control external lighting systems based on natural light readings, and also allows the microcontroller to control lighting based on a given schedule.

In the particular case, one of the outputs of the microcontroller can be connected to a backup cooling fan, and one of the inputs is connected to a thermostat sensor. In additional particular cases, the outputs of the microcontroller are connected to a device for displaying information about the status of the controller, and a remote control device. In these particular cases, automatic shutdown in case of an accident, continuous monitoring of the health of power elements, digital indication of operating modes, logging of parameters and operating modes in non-volatile memory, remote mechanical control on / off load, as well as on / off power saving mode, as well as remote control of the operating mode and diagnostics of the lighting installation, which significantly expands the functionality of the regulate pa compared to the known analogues.

The utility model is explained in more detail below on the example of its implementation with reference to the voltage regulator circuit (hereinafter referred to as the regulator) shown in FIG.

The controller contains an adjustment unit, which includes the autotransformer 1, with taps that are connected to the corresponding adjustment switches T1-T6. The controller control unit contains a microcontroller 2, the inputs of which are connected to an input voltage sensor 5, an output voltage sensor 6, a load current sensor 7, an ambient light sensor 8, temperature thermostats 9, 10 and a mechanical remote control device 11, and the outputs of the microcontroller are connected to the control inputs of the voltage adjustment switch T1-T6, a backup cooling fan 12, a device for adjusting the brightness of lighting devices with a voltage of 0-10 V DC 15, a device from Information about the status of the regulator 3, and the remote control device 4.

The adjustment switches T1-T6 are made as electronic - thyristor blocks, consisting of pairs of countercurrently connected thyristors connected to the taps of the autotransformer 1. The thyristor blocks are controlled, for example, by the MOS3083 microcircuit.

Remote control is carried out on the basis of the open international standard for the interaction of building automation systems ISO / IEC 14908.1 using the FTT10 transceiver as part of a free topology communication network. Remote control device 4 provides the following information: level of supply voltage, voltage and load current; current state of the regulator; protocol of controller states and power parameters of the lighting installation.

The remote control device 4 also provides the following control actions: turning on / off the power of the lighting system; enable / disable the energy-saving power mode of the lighting system; adjustment of the light level setting for automatic control of the lighting system; setting the schedule for switching the lighting installation modes in accordance with the operating schedule of a particular lighting object; setting parameters for logging the operation of the regulator; loading an algorithm for automatically controlling the voltage at the load in order to save energy for a lighting system with certain P-U characteristics.

The regulator operates as follows.

The input voltage from the terminals of the INPUT connector after turning on the circuit breaker 14 is supplied to the autotransformer 1. The microcontroller 2 uses the input voltage sensor 5 to measure the magnitude of the input voltage. If the input voltage is less than the lower limit of the specified voltage range within the permissible error according to GOST 13109-97, then the microcontroller 2 connects the boost winding of the autotransformer 1. The selection of the winding is made in accordance with the deviation value. If the input voltage is greater than the upper limit of the specified voltage range within the permissible error in accordance with GOST 13109-97, then the microcontroller 2 connects the step-down winding of the autotransformer 1. The selection of the winding is made in accordance with the deviation value. This is how the controller is initially turned on.

Further operation of the controller occurs as follows: when the input voltage is changed using the input voltage sensor 5 in the rated voltage range of the network, the controller control device sends commands to the control inputs of the adjustment switches T1-T6, which switch the taps of the autotransformer 1 in such a way as to provide voltage to the output of the controller corresponding to the nominal range of the output voltage within the permissible error according to GOST 13109-97. If the input voltage becomes less than the lower limit of the specified voltage range within the permissible error according to GOST 13109-97, then the microcontroller connects the boost winding of the autotransformer 1. The selection of the winding is made in accordance with the deviation value. If the input voltage becomes greater than the upper limit of the set voltage range within the permissible error in accordance with GOST 13109-97, then the microcontroller 2 connects the lowering winding of the autotransformer 1. The selection of the winding is made in accordance with the deviation value.

In accordance with the defined P-U characteristics of the connected lighting system, it is possible to change the voltage level to provide an energy-saving mode. It will also be possible for a specialist to determine an algorithm for gradually increasing voltage on lighting devices to values according to GOST 13109-97, providing a sparing start-up mode, which helps to extend the lamp life. In addition, the operating modes of the lighting installation can be controlled based on information about the external illumination and the operating schedule of the lighting object.

The control is as follows, if a sufficient level of ambient light is detected (using the light sensor 8), then the lighting system is turned off. If the lighting level drops below the set value, the lighting system is switched on. A temporary control hysteresis may be provided, as well as a hysteresis by the value of the change in illumination. The operation schedule of the lighting object determines working, non-working hours and holidays. During non-working hours, lighting can be operated in an energy-saving mode at a reduced supply voltage in accordance with the characteristics of the luminaires used.

The accuracy of regulation is determined by the magnitude of the voltage between adjacent branches, a high speed of measurement of the parameters is achieved by sampling the measurement of the input voltage, output voltage, load current for one period of the mains voltage, which provides an AC voltage regulation time of 50 Hz when going beyond the range of permissible steady-state deviations according to GOST 13109-97 no more than 20 ms.

The measurement results of the input and output voltages, power consumption, and other auxiliary parameters, the microcontroller outputs to the device 3 display information about the status of the controller. When the input voltage changes in the nominal range, the controller control unit (microcontroller 2) sends commands to the control inputs of the T1-T6 switches, which connect one of the taps of the autotransformer 1 in such a way as to provide a voltage on the load that corresponds to the nominal output voltage range within the permissible error.

Switching is performed after the driver chip of the thyristor blocks determines the moment of current transfer in the load circuit through zero. The stabilization accuracy is determined by the voltage between adjacent taps of the autotransformer, so with 6 taps of the autotransformer, the nominal input voltage range is from 150 V to 290 V with a stabilization accuracy of ± 5%, which ensures compliance with the requirements of GOST 13109-97 to the steady-state deviation of the load voltage. The accuracy can vary by changing the number of transformer windings and the number of adjustment switches, thereby ensuring the creation of high-precision voltage regulators based on the proposed model. Switching at zero current eliminates network voltage distortion. Additionally, MOS 3083 microcircuits provide galvanic isolation of the control device from power circuits.

If the input voltage exceeds the operating range, which slightly exceeds the nominal range, the controller control unit turns off all the taps of the autotransformer 1 involved in the regulation, the output voltage to the terminals is stopped. After normalizing the input voltage, that is, when the input voltage reaches the operating range, the control unit resumes the work on regulating the output voltage. In addition, the controller control unit can monitor a number of emergency situations, when they occur, the output voltage to the load connection terminals is cut off. The microcontroller outputs information about emergency situations to the device displaying information about the status of the regulator and transmits it via the remote control interface.

Thus, the claimed voltage regulator allows you to:

1) Regulation of the voltage at the load in accordance with the requirements of GOST 13109-97 to the range of permissible steady-state voltage deviations;

2) Power supply of lighting systems in a mode that allows to reduce energy consumption and extend the service life;

3) Management of outdoor lighting systems based on natural light and a calendar of use;

4) Regulation of the luminous flux of lighting systems equipped with start-up and control equipment, equipped with a 0-10 V control input;

5) Continuous monitoring of input and output voltage;

6) Continuous monitoring of load current;

7) Automatic shutdown in case of an accident;

8) Continuous monitoring of the health of power elements;

9) Digital indication of operating modes;

10) Logging of parameters and operating modes in non-volatile memory;

11) Remote mechanical control of turning on / off the load, as well as turning on / off the energy-saving mode;

12) Remote control of the operating mode and diagnostics of the lighting installation.

In conclusion, it should be noted that the above specific examples are intended only to better understand the essence of the utility model and cannot be considered as limiting the scope of the requested legal protection, which is determined solely by the attached formula.

Claims (5)

1. The voltage regulator for lighting systems, which includes an adjustment unit, as well as a control unit, characterized in that the adjustment unit contains an autotransformer and voltage adjustment switches connected to its taps, and the control unit contains a microcontroller, the inputs of which are connected to at least a sensor input voltage, output voltage sensor, load current sensor, and the outputs are connected at least to the control inputs of the voltage adjustment switches, providing a signal m of the microcontroller, switching the taps of the autotransformer to obtain the calculated output voltage at the load. 2. The controller according to claim 1, characterized in that it also contains an ambient light sensor connected to one of the inputs of the microcontroller, and a device for adjusting the brightness of lighting devices with a voltage of 0-10 V DC connected to one of the outputs of the microcontroller. 3. The controller according to any one of claims 1 or 2, characterized in that one of the outputs of the microcontroller is connected to a backup cooling fan, and one of the inputs is connected to a thermostat sensor. 4. The controller according to any one of claims 1 or 2, characterized in that the outputs of the microcontroller are connected to a device for displaying information about the status of the controller. 5. The controller according to any one of claims 1 or 2, characterized in that the outputs of the microcontroller are connected to a remote control device.