RU169965U1 - Optical source - Google Patents

Abstract

The utility model extends the scope of the optical radiation source. The specified technical result is achieved by the fact that in the optical radiation source containing a single-phase bridge on diodes 1-4, the input terminals of which are connected to the input terminals of the source through the protective element 5 and the capacitive circuit 6, shunted by the resistor 7, and the output terminals are shunted by the second capacitive circuit 8 and a second resistor 9, an analog DC controller 10, the VIN terminal of which is connected to the positive output terminal of the bridge through the LED circuit 11, the GND terminal is connected to the VIN terminal through the third capacitive circuit 12 and to the negative output terminal of the bridge directly or through the second LED circuit 13, and the IS terminal is connected to the GND terminal through the third resistor 14. The ratio of the direct voltage on the LED circuit or the sum of the direct voltages on the LED circuit and the second LED circuit to the maximum voltage on the input terminals of the source equal to 0.15 ... 0.97. The LED circuit can be additionally shunted by the fourth capacitive circuit 15 and the fourth resistor 16, the second LED circuit is shunted by the fifth capacitive circuit 17 and the fifth resistor 18, and the VIN terminal of the controller is connected to the positive output terminal of the bridge through a series-connected protective diode 19 and an LED circuit. 1 s.p. f-ly, 1 ill.

Description

The utility model relates to lighting engineering and can be used in the design of new energy-efficient sources of optical radiation with increased service life, universal, designed for both indoor and outdoor installations. The utility model is aimed at expanding the scope of the optical radiation source.

A known source of optical radiation containing a single-phase bridge on diodes, the input terminals of which are connected to the input terminals of the source, an analog DC controller, the output OUT1 of which is connected to the positive output terminal of the bridge through the LED matrix, the output OUT2 is connected to the output OUT1 through the second LED matrix, the output OUT3 is connected to OUT2 through a third LED matrix, OUT4 is connected to OUT3 through a third LED, controller GND is connected to a negative output bridge directly, and the REXT pin is connected to the GND pin through a resistor (SM2087 High Power Factor Linear Constant Current LED Driver (datasheet) // www.dianyua-nic.com).

A disadvantage of the known source of optical radiation is the high pulsation coefficient of the light flux, reaching 100%. The noted drawback significantly narrows the scope of the source.

A known optical radiation source containing a single-phase bridge on diodes, the input terminals of which are connected to the input terminals of the source, and the output terminals are shunted by a capacitor, an analog DC controller, the OUT terminal of which is connected to the positive output terminal of the bridge through an LED matrix, the GND terminal of the controller is connected to the negative the output pin of the bridge directly, and the REXT pin is connected to the GND pin through a second resistor (SM2082B Single Channel LED Constant Current Driver (datasheet) // www.dianyua-nic.com).

The disadvantages of the known source of optical radiation are a significant inrush current, lack of protection against short circuits and surge surges at the input, a high level of radio noise, a relatively low power factor and a high harmonic coefficient of the current consumed from the mains, equal, respectively, 0.45-0.65 and 120-135%. The noted disadvantages significantly narrow the scope of the optical radiation source.

A known optical radiation source containing a single-phase bridge on diodes, the input terminals of which are connected to the input terminals of the source through a fuse, and the output terminals are shunted by a capacitor, an analog DC controller, the OUT terminal of which is connected to the positive output terminal of the bridge via an LED matrix, the GND terminal of the controller is connected to the OUT pin through the capacitor and to the negative bridge pin directly, and the REXT pin is connected to the GND pin through a resistor (SM2082B Single Channel LED Constant Current Drive r (datasheet) //www.dianyua-nic.com).

The disadvantages of the source are a significant inrush current, lack of protection against surge surges at the input, a high level of radio noise, a relatively low power factor and a high harmonic coefficient of the current consumed from the mains, equal to 0.45-0.65 and 120-135%, respectively. The noted disadvantages significantly narrow the scope of the optical radiation source.

A known optical radiation source containing a single-phase bridge on diodes, the input terminals of which are connected to the input terminals of the source, and the output terminals are shunted by a capacitor, an analog DC controller, the VIN pin of which is connected to the positive output terminal of the bridge through an LED matrix, the GND terminal of the controller is connected to the negative the output pin of the bridge directly, and the pin IS is connected to the GND pin through a resistor (RT6913A / B Current Regulator for HV-LED (datasheet) // www.prinzeton.com.tw).

A known source of optical radiation is the closest in technical essence to a utility model and is selected as a prototype.

The disadvantages of the prototype are a significant inrush current, the lack of protection against surge surges at the input and short circuits, a high level of radio interference, a relatively low power factor and a high harmonic coefficient of the current consumed from the mains, respectively 0.45-0.65 and 135-155% . At small values of the capacitance of the capacitor, the pulsation levels of the light flux increase. The source cannot be used for small values of the ratio of the direct voltage on the LED matrix to the maximum voltage at the input terminals of the source due to overheating, lowering the output current of the controller and the efficiency (and also output power) of the device. The noted disadvantages significantly narrow the scope of the optical radiation source.

The utility model is aimed at solving the problem of expanding the field of application of the optical radiation source, which is the purpose of the utility model.

This goal is achieved by the fact that in the optical radiation source containing a single-phase bridge on diodes, the input terminals of which are connected to the input terminals of the source through a protective element and a capacitive circuit shunted by a resistor, and the output terminals are shunted by a second capacitive circuit and a second resistor, an analog DC controller the VIN pin of which is connected to the positive bridge output terminal via an LED circuit, the GND terminal is connected to the VIN terminal through a third capacitive circuit and to the negative output terminal at the bridge directly or through a second LED circuit, and the IS terminal is connected to the GND terminal through a third resistor, the ratio of the direct voltage on the LED circuit or the sum of the direct voltages on the LED circuit and the second LED circuit to the maximum voltage on the input terminals of the source is 0.15 ... 0.97.

According to claim 1, the LED circuit is shunted by the fourth capacitive circuit and the fourth resistor, the second LED circuit is shunted by the fifth capacitive circuit and the fifth resistor, and the VIN terminal of the controller is connected to the positive output terminal of the bridge through a series-connected protective diode and LED circuit.

A significant difference that characterizes the utility model is the expansion of the scope of the optical radiation source by improving its technical characteristics and possible design options. The inventive optical radiation source has a relatively high power factor (up to about 70%) and a low level of radio interference, protection against short circuit and surge voltage at the input, has a relatively low harmonic coefficient of the current consumed from the network (up to less than 30%) and provides low ripple luminous flux (5-10%). Inrush current surges when the optical radiation source is turned on may be practically absent. The device operates efficiently with a high efficiency and reliability in a fairly wide range of ratios of the direct voltage on the LED circuit or the sum of the direct voltages on the LED circuit and the second LED circuit to the maximum voltage at the input terminals of the source (0.15 ... 0.97).

The expansion of the scope is due to new principles of the device and a new design of the source, a new electrical circuit, the implementation of the input circuit of the controller, new elements and connections, that is, the hallmarks of the utility model. Thus, the distinguishing features of the claimed source of optical radiation are significant.

The drawing shows an electrical diagram of an optical radiation source.

The optical radiation source contains a single-phase bridge on diodes 1-4, the input terminals of which are connected to the input terminals of the source through a protective element 5 and a capacitive circuit 6, shunted by a resistor 7, and the output terminals are shunted by a second capacitive circuit 8 and a second resistor 9, an analog DC controller 10, the VIN terminal of which is connected to the positive output terminal of the bridge through the LED circuit 11, the GND terminal is connected to the VIN terminal through the third capacitive circuit 12 and to the negative output terminal of the bridge directly or through the second LED circuit 13, and the IS terminal is connected to the GND terminal through the third resistor 14. The ratio of the forward voltage on the LED circuit or the sum of the direct voltages on the LED circuit and the second LED circuit to the maximum voltage on the input terminals of the source is 0.15 ... 0 97. The LED circuit can be additionally shunted by the fourth capacitive circuit 15 and the fourth resistor 16, the second LED circuit is shunted by the fifth capacitive circuit 17 and the fifth resistor 18, and the VIN terminal of the controller is connected to the positive output terminal of the bridge through a series-connected protective diode 19 and an LED circuit.

The optical radiation source in the steady state operates as follows.

The LEDs of an LED circuit or circuits (LED arrays 11, 13) generate optical radiation in the range of visible light or infrared (ultraviolet) parts of the spectrum. An analog DC controller 10 stabilizes the current through the LEDs of the circuit or circuits (11, 13), which is necessary for their normal operation. In this case, the current level through the LEDs of the LED circuit (or circuits 11, 13) is set using a resistor 14 (pins IS, GND of the controller 10). The capacitor 12 (conclusions VIN, GND of the controller 10) provides a reduction in the magnitude of the electromagnetic interference and emissions that occur during operation of the active elements of the analog controller 10.

The device is connected to the input terminals through the protective element 5 and the capacitive circuit 6, shunted by the resistor 7. The protective element 5 may be a conventional resistor with low resistance or a fuse or any of the known circuits that additionally contain filter chokes, capacitors, varistor. The latter option is most preferred. A fuse or resistor of the protective element 5 protects the optical radiation source from short circuit. At the same time, the resistor (chokes, if installed) of the protective element 5 limits the inrush current surge, as well as the amplitude of the surge currents that occur when charging capacitance circuits (capacitors) 6, 8. The varistor of the protective element 5 (if used) limits the levels of surge voltage at the input terminals of the optical radiation source.

Capacitive circuit 6 reduces (limits) the voltage level at the input terminals of a single-phase bridge (1-4). The voltage level at the input terminals of a single-phase bridge (1-4) depends on the value of the capacitance of the capacitive circuit 6 (with an increase in the capacitance of the capacitive circuit 6, the voltage level at the input terminals of the single-phase bridge (1-4) increases). Thus, the matching of the forward voltage values on the LED circuit 11 or the sum of the direct voltages on the LED circuit 11 and the second LED circuit 13 and the maximum voltage at the input terminals of the source is ensured.

The bridge (diodes 1-4) can be implemented on discrete elements or have an integral design (for example, MBS10F or KTs407). The principle of operation of the device, however, remains unchanged.

Capacitive circuit 8 serves to filter the output voltage of a single-phase bridge (diodes 1-4). The quality of filtration increases with increasing value of the capacitance of the capacitive circuit 8 (this reduces the level of pulsation of the light flux of the source). However, an excessive increase in the capacitance of the capacitive circuit 8 leads to a decrease in the power factor of the optical radiation source and an increase in the harmonic coefficient of the current consumed from the network, as well as the levels of electromagnetic interference and radiation. The installation of additional capacitive circuits 15 and 17 reduces the level of pulsation of the light flux. In this case, the effect on the power factors and the shape of the input current of the device is less significant. To exclude reverse voltage on the controller 10 when using capacitive circuits 15 and 17, a protective diode 19 is introduced into the device circuit.

All capacitive circuits (6, 8, 15, 17), except for the capacitive circuit 12, which has a small capacitance value, are shunted by resistors (respectively, 7, 9, 16, 18). Resistors 7, 9, 16, 18 are designed to discharge the capacitance of capacitive circuits (6, 8, 15, 17) when the device is turned off and have large resistance values that practically do not affect the operation of the device in nominal mode.

All capacitive circuits (6, 8, 12, 15, 17) can be made up of one or more capacitors connected in series, in parallel or in series and in parallel.

Similarly, LED circuits 11, 13 can be arranged. LED circuits (11, 13), in addition, are performed on discrete LEDs or LED matrices (rulers, filaments).

The principle of operation of the optical radiation source, in these cases, does not change.

In the device, during its technical implementation, it can be used (in the protective element 5), for example, a varistor of the type 10D471 (the voltage of the optical radiation source is 220-230 V).

The device is connected to the input terminals, as noted above, through the protective element 5 (fuse, resistor and / or inductance, or a more complex circuit). Element 5 protects the optical radiation source from short circuit (fuse, resistor). In addition, the protective element 5 (resistor, inductance) can limit the inrush of the inrush current, as well as the inrush amplitudes and the harmonic coefficient of the current consumed from the network (operating currents) arising from the charging of capacitors of capacitive circuits 6, 8. The protective element 5 (inductance) reduces electromagnetic interference arising from the operation of the device.

The technical solutions of the claimed utility model for arranging the input circuits of the source and controller (protective element, capacitive circuits, rectifier, LED circuit or circuits) are applicable for any type of DC controllers of a similar purpose (for example, РТ6913А / В, РТ6923, SM2082, SM2087, ZONOPO8062, ACS1004, ACS1404, CL8800, BP2831 and others). For some types of analog controllers in the technical documentation, outputs similar in purpose can be indicated differently (OUT, REXT, and so on). In some cases, to increase the load capacity of the findings of the type of enclosure used, the corresponding outputs of the controllers are doubled. In some cases, to increase the output current of the device, several analog DC controllers can be switched on for parallel operation. The principle of operation of the optical radiation source in these cases is preserved. Therefore, the considered technical solutions also apply to the implementation options of the claimed utility model.

Capacitive circuits 6, 8, 12, 15, 17 can (as indicated above) consist of one or several capacitors connected in series, in parallel or in series and in parallel. LED circuits 11 and 13 are also made of one or several LEDs, LED arrays or LED arrays connected in series, in parallel or in series and in parallel. Since the principle of operation of the device does not change from this, the considered circuit options also represent options for implementing the utility model.

Compared with the prototype, the scope of the new optical radiation source is significantly expanded.

The inventive source meets current requirements for the technical characteristics of such devices.

Indeed, a new source of optical radiation can be used more efficiently for both indoor and outdoor installations, as well as in closed luminaires of limited volume in various lighting systems or in special generators of infrared or ultraviolet radiation, including in unstable networks.

The nomenclature of type designs of optical radiation sources according to the new scheme is expanding significantly. Each type design can be an optimal design and a fairly technological product, which reduces, in particular, the final price of the products.

A new source of optical radiation provides effective matching of the levels of direct voltage on the LED circuit or the sum of the direct voltages on the LED circuit and the second LED circuit to the maximum voltage at the input terminals, reducing inrush currents, protection against short circuits and overvoltages at the input terminals.

The power factor for the inventive source increases (by 15-20%). In this case, the harmonic coefficient of the current consumed from the network decreases by 3-4 times and does not exceed 30%. The pulsations of the light flux (radiation flux) remain at a relatively low level (5-10%).

The optical radiation source also has low levels of radio interference and emissions (not exceeding the established standards).

A new source of optical radiation provides operation with a higher efficiency in a wide range of input voltages.

The expansion of the scope of the optical radiation source is provided by all of the above properties and advantages over known devices of a similar purpose.

Claims (2)

1. An optical radiation source containing a single-phase bridge on diodes, the input terminals of which are connected to the input terminals of the source through a protective element and a capacitive circuit shunted by a resistor, and the output terminals are shunted by a second capacitive circuit and a second resistor, an analog DC controller, whose VIN pin is connected with a positive bridge output via an LED circuit, a GND pin is connected to the VIN pin through a third capacitive circuit and to a negative bridge output directly or via volt an open LED circuit, and the IS terminal is connected to the GND terminal through a third resistor, the ratio of the forward voltage on the LED circuit or the sum of the direct voltages on the LED circuit and the second LED circuit to the maximum voltage on the input terminals of the source is 0.15 ... 0.97. 2. The optical radiation source according to claim 1, characterized in that the LED circuit is shunted by the fourth capacitive circuit and the fourth resistor, the second LED circuit is shunted by the fifth capacitive circuit and the fifth resistor, and the VIN terminal of the controller is connected to the positive output terminal of the bridge through a series-connected protective diode and LED circuit.

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