RU88876U1 - DIRECT CURRENT REGULATOR (OPTIONS) - Google Patents

Abstract

1. A rectified current regulator containing an electronic switch control circuit with input sensors for feedback channels and a rectifier with a power factor corrector and an output capacitor filter and a T-shaped pulse modulator consisting of a choke, the first electronic key, connected in cascade between the input and output terminals of the device connected in the conducting direction relative to the polarity of the capacitor filter, and the first diode connected in the non-conducting direction relative to the polarity the output terminals of the device, characterized in that a second unidirectional electronic key is inserted into it, connected in parallel with the modulator throttle in series with the first electronic key. ! 2. The rectified current controller according to claim 1, characterized in that the electronic switch control circuit includes a feedback channel between the voltage sensor on the capacitor filter and the control circuit of the first electronic switch, as well as a feedback channel between the device of the average pulse value of the output current of the device and the control circuit second electronic key. ! 3. A rectified current regulator containing an electronic switch control circuit with input sensors for feedback channels and a rectifier with a power factor corrector and with an output capacitor filter and a T-shaped pulse modulator consisting of a choke, the first electronic switch, connected in cascade between the input and output terminals of the device connected in the conductive direction relative to the polarity of the capacitor filter, and the first diode included in the non-conducting �

Description

The utility model relates to pulsed power electronics and can be used to create secondary power sources operating in a wide range of ambient temperatures (for example, from -60 ° C to + 105 ° C).

A known rectified current regulator (analog) containing a control circuit for electronic keys with output sensors of feedback channels and a rectifier with a power factor corrector and with an output capacitor filter and a pulse modulator having a choke, electronic keys and sequentially connected between the input and output terminals of the device diodes (A. Evstifeev. Features of the construction of ballasts for high pressure lamps. Power Electronics, No. 3, 2008, p.132-136, Fig. 4, 5, 6, 10, 11).

The disadvantage of this device (analogue) is its low reliability and operating life due to the presence of an electrolytic capacitor filter with a relatively large energy consumption that requires thermal stabilization at a wide range of ambient temperatures (for example, from -60 ° С to + 105 ° С indicated in the analogue, for street location of the device near a warming load).

A known rectifier current regulator comprising a control circuit for electronic keys with output sensors of feedback channels and a rectifier with a power factor corrector and with an output capacitor filter and a T-shaped pulse modulator consisting of a choke, an electronic key, is connected in series between the input and output terminals of the device and diode (A. Vasiliev, V. Khudyakov, V. Khabuzov. Analysis of modern methods and technical means of power factor correction for pulsed devices. Silov I Electronics, №2, 2004, s.72-77, Figure 9).

The disadvantage of this device (prototype) is also its low reliability and operating life due to the presence of an electrolytic capacitor filter with a relatively high energy intensity, requiring thermal stabilization at a wide range of ambient temperatures (for example, from -60 ° C to + 105 ° C).

In terms of technical nature, the closest (prototype) to the proposed one is the last of these known rectified current regulators.

The task to which the claimed utility model is directed is to eliminate a non-heat-resistant electrolytic smoothing capacitor with a relatively high energy intensity by replacing it with a heat-resistant inductor filter combined with a pulse modulator inductor.

The technical result of the proposal is to increase the reliability and working life of the device, designed to operate in a wide range of ambient temperatures.

The indicated result in the first embodiment is ensured due to the fact that a rectifier with a power factor corrector and an output capacitor filter and a T-shaped pulse pulse are included in the rectified current controller, which contains an electronic switch control circuit with input sensors of feedback channels and cascadely connected between the input and output terminals of the device a modulator consisting of a throttle, a first electronic switch included in the conductive direction relative to the polarity of the capacitor filter, and first about a diode connected in a non-conductive direction with respect to the polarity of the output terminals of the device, a second unidirectional electronic key is inserted, connected in parallel with the modulator inductor in series with the first electronic key, and also because the electronic key control circuit contains a feedback channel between the voltage sensor on the capacitor the filter and the control circuit of the first electronic key, as well as the feedback channel between the sensor of the average pulse value of the output current of the device chain-keeping and management of the second electronic switch.

The indicated result according to the second embodiment is ensured due to the fact that the rectifier with a control circuit of electronic keys with input sensors of feedback channels and a cascade rectifier with a power factor corrector and with an output capacitor filter and a T-shaped pulse filter are connected in cascade between the input and output terminals of the device a modulator consisting of a throttle, a first electronic switch included in the conductive direction relative to the polarity of the capacitor filter, and first about a diode connected in a non-conductive direction with respect to the polarity of the output terminals of the device, a second unidirectional electronic switch is introduced, connected in parallel with the output terminals of the pulse modulator connected to the inductor and the first diode, and also supplemented by a second diode, which is connected in series with one of its first output, and the second - with one of the output terminals of the device, and also due to the fact that the electronic key control circuit contains a feedback channel between the voltage sensor capacitor bank and the filter control circuit of the first electronic key, and channel feedback sredneimpulsnogo between sensor output current device and the second electronic control circuit of the key.

An additional technical result of the proposal is the exclusion of the generation of a powerful electromagnetic pulse during an emergency circuit or breakdown in a circuit associated with an energy-intensive capacitor filter.

Laboratory tests of the device model and studies on a computer model confirm the possibility of wide industrial use of the proposed rectified current regulator.

Figure 1 shows a schematic diagram of the proposed regulator of the rectified current in the first embodiment, based on the "lowering" pulse modulator.

Figure 2 shows the same circuit, but with a "boosting" pulse modulator (for the first option).

Figure 3 shows the same circuit, but with an "up-down" (polar-inverting) pulse modulator (for the first option).

Figure 4 shows a schematic diagram of the proposed regulator of the rectified current in the second embodiment based on the "lowering" pulse modulator.

The proposed rectified current controller (2 options) contains, according to both options (Figs. 1, 2, 3, 4): a control circuit 1 of electronic keys and a rectifier 6 with a power factor corrector cascaded between the input 2, 3 and output 4, 5 outputs of the device 7 and with an output capacitor filter 8, a T-shaped pulse modulator 9, consisting of a choke 10, a first electronic switch 11 and a first diode 12, as well as a second unidirectional electronic switch 13. The input terminals of the feedback channel of the electronic key control circuit are connected with a rectified voltage sensor 14, a voltage sensor on the capacitor filter 15, an output voltage sensor 16, with a rectified current sensor 17 and an average pulse output current sensor 18. In the second embodiment, a second diode 19 is added (Figure 4).

The first electronic switch 11 is included in the conductive direction relative to the polarity of the capacitor filter 8. The first diode 12 is included in the non-conductive direction relative to the polarity of the output terminals 4, 5 of the device. The second electronic switch 13 according to the first embodiment is connected in parallel with the inductor 10 of the modulator 9 and sequentially counter to the first electronic switch 11, and according to the second embodiment, it is connected in parallel with the output terminals of the pulse modulator 9 connected to the inductor 10 and the first diode 12, and is also supplemented with the second diode 19 , which, with its first output, is connected in series with the first electronic key 11, and the second with one of the output terminals 4, 5 of the device.

Dotted lines and parentheses in all of FIGS. alternative locations of elements are shown that do not change the operating principle of the device and are taken into account in the generalized notation of the utility model formula.

As the first electronic key 11, either a transistor, or a lockable (two-operation) thyristor can be used, and as the second 13 - a serial transistor-diode pair, or any thyristor (one- or two-operation), because its artificial locking can be provided by short-term inclusion of the first key 11.

The control circuit 1 of the electronic keys contains a feedback channel between the sensors of the rectified voltage 14 and the voltage on the capacitor filter 15 and the control circuit of the first electronic key 11, as well as feedback between the sensor of the average pulse value of the output current of the device 18 and the control circuit of the second electronic key 13. The same the channel may also be equipped with a feedback circuit with an output voltage sensor 16 for the purpose of protection and correction.

The main differences of the proposed device from its analogue and from the prototype are a significant reduction in the energy intensity of the capacitor filter 8, increasing the energy intensity of the inductor 10 and the introduction of the second electronic key 13.

The proposed regulator of the rectified current operates as follows. The input terminals 2, 3 of the device are connected to the AC mains, and the output 4, 5 is connected to a unipolar capacitive, resistive, semiconductor, gas-discharge or mixed load, for example, to an LED pole, a battery, a half-bridge or bridge voltage inverter, etc.

The function of the power factor corrector is to provide a given sinusoidal current consumed from the network, as well as its in-phase synchronization with the network voltage.

With a relatively small electric capacity of the capacitor filter 8, the input medium-pulse current and voltage of the pulse modulator 9 approach the shape of the pulsating - sinusoidal (in absolute value proportional to | sinωt |) values. This is provided by the feedback channel between the voltage sensor on the capacitor filter 8 and the pulse circuit (for example, pulse-width or two-threshold) control of the first electronic key. If, at the same time, the output of the device needs to be regulated, for example, to stabilize the load current, then this is ensured by the feedback channel between the sensor of the average pulse value of the output current of the device and the control circuit of the second electronic switch 13 (also, for example, pulse-width or double-threshold). For protection against overcurrents and overvoltages and for correction of control circuits, a feedback circuit can be used for the output voltage or current of the inductor. As a result of the specified control at the input and output of the device, as well as at the input of the pulse modulator 9, a balance of average power values for a half-period of the supply (mains) voltage is achieved. In this case, the difference in the instantaneous values of these powers is compensated by the relatively large energy intensity of the inductor.

So, for example, with synchronous current and voltage at the input of a pulse modulator proportional to the law i (t) and u (t) ~ | sinωt |), the instantaneous power consumed by its input will change according to a law proportional to the function p (t) ~ 0.5 (1-cos2ωt), where ω = 2π / T _NETWORKS . If at the same time the load consumes constant power proportional to the value of P _H = P _CP ~ 0.5, then the reactive power of the inductor will be proportional to the value of Q (t) = ΔP (t) ~ 0.5cos2ωt, i.e. is a harmonic alternating function. In this case, the throttle energy is proportional to W (t) ~ ∫ΔP (t) dt + W ₀ = sin2ωt + W ₀ , i.e. will be in the form of a pulsating quantity with an arbitrarily given (preferably minimal) constant component.

The inductor current will vary according to a law proportional to where L is the inductance of the inductor.

Thus, the task that the claimed utility model is aimed at is solved - the non-heat-resistant electrolytic smoothing capacitor with a relatively high energy intensity is eliminated by shifting its function to a heat-resistant choke filter, combined with a pulse modulator choke.

At the same time, the technical result of the proposal is achieved - increasing the reliability and working life of the device designed to operate in a wide range of ambient temperatures.

Claims (4)

1. A rectified current regulator containing an electronic switch control circuit with input sensors for feedback channels and a rectifier with a power factor corrector and an output capacitor filter and a T-shaped pulse modulator consisting of a choke, the first electronic key, connected in cascade between the input and output terminals of the device connected in the conducting direction relative to the polarity of the capacitor filter, and the first diode connected in the non-conducting direction relative to the polarity the output terminals of the device, characterized in that a second unidirectional electronic key is inserted into it, connected in parallel with the modulator throttle in series with the first electronic key. 2. The rectified current controller according to claim 1, characterized in that the electronic switch control circuit includes a feedback channel between the voltage sensor on the capacitor filter and the control circuit of the first electronic switch, as well as a feedback channel between the device of the average pulse value of the output current of the device and the control circuit second electronic key. 3. A rectified current regulator containing an electronic switch control circuit with input sensors for feedback channels and a rectifier with a power factor corrector and with an output capacitor filter and a T-shaped pulse modulator consisting of a choke, the first electronic switch, connected in cascade between the input and output terminals of the device connected in the conducting direction relative to the polarity of the capacitor filter, and the first diode connected in the non-conducting direction relative to the polarity device leads, characterized in that a second unidirectional electronic switch is inserted into it, connected in parallel with the output terminals of the pulse modulator connected to the inductor and the first diode, as well as supplemented by a second diode, which is connected in series with it with its first output, and the second with one of the output pins of the device. 4. The rectified current regulator and its variants according to claim 3, characterized in that the electronic switch control circuit includes a feedback channel between the voltage sensor on the capacitor filter and the control circuit of the first electronic switch, as well as a feedback channel between the sensor of the average pulse value of the output current of the device and the control circuit of the second electronic key.