UA66523A - Emitting device - Google Patents

Abstract

The proposed emitting device is connected to a power-supply unit and contains a power converter and emitting elements with current limiters. The converter contains a rectifier with capacitive filter, a voltage regulator that is connected to the output of the rectifier, and a varistor connected in parallel between the rectifier and the voltage regulator. The emitting elements are connected in parallel and in series and connected to the output terminals of the converter via a protection unit. The protection unit contains a fuse, an inductance coil, and a switch that are connected in series and connected in the output circuit of the converter, and a voltage transducer. The voltage transducer isconnected to the terminals of the converter. The control input of the switch is connected to the output of the voltage transducer via a resistor. The emitting elements are combined into groups, each of which contains an electronic shunting switch.

Description

Description of the invention

The invention relates to radiating technology and can be used in signaling, lighting and 2 other devices based on the use of radiating elements (infrared visible light, ultraviolet radiation, etc.).

The closest in terms of technical essence and the technical result that is achieved is the radiating device given in the description of patent Mo2151473 of the Russian Federation for an invention dated 06.25.1998, publ. 06/20/2000, M. Cl. 7 НОБ5В37/00, Е2154/00. 70 A known radiating device connected to a source of electrical energy contains an electrical energy converter including a rectifier with a capacitive filter and a supply voltage stabilizer connected in series, and parallel-serial chains of radiating elements with current limiters connected in parallel to the outputs of the electrical energy converter.

The electrical energy converter in it is made on the basis of a rectifier (bridge diode circuit) and a parametric voltage stabilizer, which contains a series-connected electric incandescent lamp, an additional ballast thermistor and a powerful zener diode installed on the heat sink, which limits and stabilizes the voltage on parallel-series circuits emitting elements with current limiters. LEDs are used as emitting elements, and ballast resistors are used as current limiters.

The known radiating device is not sufficiently reliable in operation, because it does not eliminate the effect of external influences (industrial interference) and temperature changes, as well as internal overvoltages that occur when any circuit element fails.

The zener diode, which is used as a stabilizing element, has limitations on the maximum current and stabilization voltage, and due to the fact that voltage surges are possible at the input of the device that exceed the nominal voltage of the power supply network, this can lead to a corresponding change in the zener diode current, which, in its 29 turn, will lead to its failure and, accordingly, to the failure of the entire device. "

The fact that the voltage to the input of parallel-series chains of radiating elements is supplied directly from the outputs of the electrical energy converter, with a sharp increase in the output voltage of the converter, for example, when one of its elements fails, leads to the supply of voltage to the input of parallel-series chains of emitting elements , which exceeds the permissible limit. This about 3o leads to the failure of the emitting elements. Gee!

In the known device, the radiating elements are connected in series chains, which are supplied by limiting elements at the input, and are connected in parallel. At the same time, if one radiating element fails, the entire chain of serially connected radiating elements fails, which violates the integrity of the radiated flow.

As current limiters in parallel-serial chains of radiating elements, resistors are used. The resistor determines the current of the circuit, which is determined by the ratio of the difference between the supply voltage and the total value of the threshold voltages of the radiating elements connected in series, to the value of its resistance. However, with external temperature fluctuations, the resistor does not prevent the current from changing in the series circuit of the emitting elements. At the same time, when the temperature of the external environment fluctuates, there is a change in the voltage drop across the radiating elements, which leads to a change in the power (intensity) of the radiated current. with Thus, the known emitting device is insufficiently reliable,

The basis of the invention is the task of improving the radiating device, in which, by introducing new elements, new connections between elements and a new implementation of the elements of the device, an increase in the degree of protection against external and internal overvoltages and preservation of the integrity of the device's electrical circuits by changing the contours of current flow is ensured according to them, due to which the reliability of the device increases. (o) The problem is solved by the fact that in the emitting device connected to the source of electrical energy, which contains an electrical energy converter, including a rectifier with a capacitive filter and a power supply voltage stabilizer, connected in series, and parallel-serial chains of emitting circuits 50 elements with current limiters, connected in parallel to the outputs of the electrical energy converter, according to the invention, the new thing is that the device additionally contains a protection unit installed between the electrical energy converter and parallel-series chains of radiating elements with current limiters, made in the form of series-connected fuse, inductor, power switch, the control input of which is connected through a resistor to the output of the voltage detector, the inputs of which and the output of the power switch 59 are connected to the outputs of the electrical energy converter, which additionally contains a varistor installed in in parallel between the rectifier and the power supply voltage stabilizer, and the radiating elements of the parallel-serial chains are combined into groups, each of which is additionally equipped with a shunting electronic element.

What is also new is that each of the current limiters is made in the form of a current stabilizer. 60 It is also new that the number of radiating elements united in groups is 1, 2, 3... M, where M is a natural number.

There is such a cause-and-effect relationship between the set of essential features of the claimed invention and the technical result achieved.

Simultaneous introduction into the radiating device of the protection unit installed between the electric energy converter and the parallel-serial chains of radiating elements with current limiters,

and made in the form of a series-connected fuse, an inductor, a power switch, the control input of which is connected through a resistor to the output of a voltage detector, the inputs of which and the output of the power switch are connected to the outputs of an electrical energy converter and the input of a varistor installed in the converter in parallel between the rectifier and the power supply voltage stabilizer, as well as the fact that the radiating elements of the parallel-serial chains are combined into groups, each of which is additionally equipped with a shunting electronic element, together with the known features of the device ensures high reliability of the radiating device.

The introduction of a protection node into the device, made and connected in the stated manner, allows to ensure reliable operation of the device by protecting the radiating elements from exceeding the supply voltage, which leads to the failure of the device.

With a sharp increase in the voltage in the voltage converter circuit, which can happen when each of the elements of the circuit fails, a sharp increase in the voltage at the inputs of the parallel-serial chains of radiating elements can lead to their failure. The protection node, made and connected as stated, /5 provides protection of radiating elements from possible voltage surges by closing the input contacts of parallel-serial chains of radiating elements with a power key. At the same time, the entire load current is closed through the power switch.

A high voltage at the input of the protection unit causes the formation of a power key control signal. The key opens and the parallel-serial chains of emitting elements are short-circuited. Current circuit 2 o It is closed through a fuse, an inductance coil and a power switch. The current caused by a sudden surge of voltage at the outputs of the voltage converter flows along the circuit, bypassing the circuit with radiating elements. At the same time, the inductance coil limits the magnitude of the shock current when the power switch is turned on. Upon reaching the value of the tripping current of the fuse, the latter opens the power circuit of the parallel-serial chains, disconnecting them from the electrical energy converter.

Thus, the introduction into the scheme of the radiating device of the protection node, executed and connected in the declared manner, allows to increase the reliability of the device. "

The introduction of a varistor connected in the stated manner into the converter prevents the occurrence of voltage surges that occur during the switching of third-party current consumers (that is, in case of external interference) at the output of the rectifier due to the fact that the internal resistance of the varistor when the applied voltage increases

From to it, sharply decreases. In the normal (non-emergency) mode, the varistor is not used as a circuit element (current does not flow through it, because its resistance is very high - above 1 MΩ), and when the tripping voltage is reached, its resistance decreases sharply (to units of Ohm) and the current flows through it , thereby providing damping of overvoltages in the power supply network.

Thus, the introduction of a varistor into the electrical energy converter included in the 5 Radiating device ensures the elimination of the influence of external electrical interference on the operation of the radiating device, excluding the failure of its elements, which increases the reliability of the device.

Combining the radiating elements of parallel-serial chains into groups and equipping each group with a shunt element in combination with other features of the device allows to increase the reliability of the device in the event of failure of individual radiating elements due to changing the circuit of the current flow in the chains to bypass the non-working circuit through the shunt element, limiting the failure of radiating 7) c elements to only one group. The number of emitting elements in the group, which can be 1, 2, 3... M, where

M is a natural number that determines the number of radiating elements that fall out of the total radiating element;" flow when one emitting element fails. At the same time, the integrity of the radiated flow of parallel-serial chains of radiating elements is mostly preserved.

Implementation of current limiters designed to determine the amount of current of radiating elements, u

Ge" in the form of current stabilizers, connected as stated, allows for any changes in the direct voltage drops on the radiating elements or for unstable supply voltage applied to

Me, parallel-serial chains of emitting elements, keep the value of the current in the chain unchanged. c This increases the stability of the radiating elements and ensures reliable operation of the device with a stable and uniform radiating flow. At the nominal (calculated) operating mode of the device, the voltage drop on the current stabilizer and its 4) current correspond to the voltage drop on the ballast resistor and its current, respectively. With temperature fluctuations or unstable supply voltage, the current stabilizer changes its internal resistance. At the same time, the current in the chains of serially connected radiating elements remains unchanged. Current stabilizer Compensates changes in voltage drops on emitting elements and supply voltage fluctuations.

Thus, the implementation of current limiters in the form of current stabilizers in combination with other features,

P that are declared increases the reliability of the device's operation with a stable radiating flux.

Fig. 1 shows an example of the schematic diagram of the electrical principle of the emitting device that is claimed. Fig. 2 shows the functional diagram of the emitting device.

The radiating device, which is connected to a source of electrical energy, contains a converter 1 of electrical energy, which includes a rectifier 2 with a capacitive filter 3, a varistor 4 and a stabilizer 5 of the supply voltage. The varistor 4 is installed in parallel between the rectifier 2 and the stabilizer 5. Parallel-serial chains 6 of radiating elements 7 65 With current limiters 8 are connected in parallel to the outputs of the converter 1 of electrical energy. Between the converter 1 of electrical energy and the parallel-serial chains 6 of the radiating elements 7, a protection unit 9 is installed. The protection unit 9 is made in the form of a fuse 10, an inductance coil 11, a power switch 12 connected in series, the control input of which is connected through a resistor 13 to the output of a voltage detector 14, the inputs of which and the output of the power switch 12 are connected to the outputs of the converter 1 electrical energy. Radiating elements 7 are combined into groups, each of which is additionally supplied with a shunting electronic element 15. At the same time, the number of radiating elements 7 combined into groups is 1, 2, Z... M, where M is a natural number, and current limiters 8 are made in the form of current stabilizers.

The radiating device, the electrical schematic diagram of which is shown in Fig. 1, contains a rectifier 2, made according to a single-phase bridge rectification scheme, containing four rectifier diodes 16 and a limiting resistor 17. The stabilizer 5 of the supply voltage, shown in figure 1, contains a resistor 18, a transistor 19, a control node 20, a reverse diode 21 , choke 22, voltage divider 23 and capacitive filter 24, which are connected according to the scheme of a step-down pulse converter of constant voltage.

These and other possible implementation schemes of the rectifier 2 and the stabilizer 5, which can be used in the claimed device, are given in the scientific and technical literature, see, for example: "Integrated microcircuits.

Microcircuit! for impulse power sources and their application", "Dodeka-XXI Publishing House", M., 2001, p. 14-22, 66, 70, 71; "Integrated microcircuits. Microcircuits for linear power sources and their application", ed. "Dodeka", M., 1998, p. 17-19, 132, 133, Yu.S. Zabrodin "Industrial electronics", "Vnisshaya shkola", M., 1982, p. 293-303, 332-335.

The device works like this.

When connecting the emitting device to the source of electrical energy, a voltage (alternating or constant regardless of polarity) is applied to the input of the electrical energy converter 1 with a capacitive filter C directly or through a step-down transformer (not shown in the figure). Rectifier 2 converts it into a constant voltage of the required polarity. At the same time, the capacitive filter C smooths out voltage ripples. The output voltage of the rectifier 2 through the varistor 4 is fed to the stabilizer 5, in which the voltage is stabilized to the required calculated values that determine the operation of the radiating elements 7.

In normal (non-emergency) mode, varistor 4 is not used as a circuit element, because its resistance is very high, and during sudden voltage surges, varistor 4 is activated, current flows through it, providing damping of overvoltage.

In the normal (non-emergency) mode, the output voltage of the electrical energy converter 1 is supplied from the protection node 9 to the inputs of the parallel-serial chains b of the radiating elements 7 with current limiters 8. At an increased (above nominal) stabilization output voltage, the voltage detector 14 generates a control signal for the power switch 12. The power switch 12 opens and closes the output current of the voltage stabilizer 5 along the circuit: fuse 10, inductance coil 11, power switch 12, thus bypassing the inputs radiating elements 7. Resistor 13 sets the value of the control current of the power switch 12. ise)

After the tripping of the fuse 10, the current circuit is interrupted, disconnecting the parallel-serial chains of radiating elements 7 from the converter 1 of electrical energy. The current limiter 8 carries out the task of current proportional to the difference in supply voltage and the amount of voltage drop on the radiating elements 7. At the same time, when using a current stabilizer as a current limiter 8, current changes in the series chain of radiating elements 7 are additionally eliminated during temperature fluctuations and "

Changes in the supply voltage. The electric current, flowing through the serially connected radiating elements 7, pt"), brings them into working condition, that is, radiation is carried out. Depending on what types of radiating elements 7 are used and in what quantity, the calculated values of the input are determined;" voltages of parallel-serial chains b of radiating elements 7. At the same time, radiating elements 7 in chains b do not stop their work when one of the radiating elements 7 in a series connection fails, because in this case only one group of radiating elements 7 fails ,

Ge" is equipped with shunting element 15, in the group to which it belongs. The number of radiating elements 7, which can vary from 1 to M, affects the integrity of the radiating flow. The greater the M, the greater the quantity

Me, radiating elements 7 does not function when the integrity of the serial chain of a group of radiating elements 7 is violated. At the same time, the current passes through the shunt element 15, ensuring the continuity of the current flow. As emitting elements 7 can be used, for example, LEDs of the infrared range 4) radiation: I-315 EK, ЖИЙ 514 СИК (RagahidnE company), AL 107, AL 161, AL 164, AL 173, (Proton company),

II-34, 1-53, KA-3528, KRI-3015 (Kipdabpoipg company); LEDs of the visible radiation range: I1-513,

Y-314, 1-593 (Ragagidn company), KSHD 40, KIPM 20 (Proton company), I-1503, 1-1513, 1-1543 (formerly Kipobgidchng company); LEDs of the ultraviolet radiation range: ETOo-50M395-30 (ETO company),

UMOM503-2395-S (the firm "U/Liusop Sogr."), and 200020M395-120 (the firm "EOTgopisv"),

P Varistors 4 can be selected from the types of SM, BIOM-5, MOSC, 014, 020 (imported production), СНИ1-1, СН2-1 (domestic production).

Stabilizers of 5 supply voltages are selected from the series: МСЗОб6ЗА/34063А, АА78540, И А5Зб6380, И АЗБбЗВ81 1200, in ЙТ1083, 171084, И 71085 (imported production), 1156EU1, 1156EU5, 1184ПНИ1, 1426ЕН22 (domestic production).

The voltage detector 14 of the protection node 9 can be selected from the series: 0С3543/44, 0С3908 (imported production), 1185SP, 1114SP1 (domestic production).

Stabilizer 8 current can be selected from the series: I M137, TsA7905, I M3171 (imported production), 65 KR1157ENTI, 142ENTI9 (domestic production).

The invention can be reproduced in production conditions on standard equipment using known components and materials.

At present, four samples of radiating devices with different typical performances are undergoing experimental and industrial tests, which show their high reliability.

Claims (2)

2 Formula of the invention 1. A radiating device connected to a source of electrical energy, which contains an electrical energy converter including a rectifier with a capacitive filter and a supply voltage stabilizer, connected 70 in series, and parallel-serial chains of radiating elements with current limiters, connected in parallel to the outputs of the electrical energy converter of energy, which is distinguished by the fact that the device additionally contains a protection unit installed between the converter of electrical energy and parallel-series chains of radiating elements with current limiters, made in the form of a series-connected fuse, inductor, power switch, the control input of which through a resistor with connected to the output of the voltage detector, the inputs of which and the output of the power switch are connected to the outputs of the electrical energy converter, which additionally contains a varistor installed in parallel between the rectifier and the power supply voltage stabilizer, and the radiating elements of the parallel-serial chains are combined in groups, each of which is additionally equipped with a shunting electronic element. 2. The emitting device according to claim 1, which is characterized by the fact that each of the current limiters is made in the form of a current stabilizer. Q. The emitting device according to claim 71, which is characterized by the fact that the number of emitting elements combined into groups is 1, 2, 3... M, where M is a natural number. « (ze) Zo sch IF) (Se) (Se) - and? (o) (o) 1 name) syu" 60 b5