RU185192U1 - POWER CORRECTOR - Google Patents

Abstract

The utility model relates to electrical engineering and can be used in power supply devices for LED lamps and LED lamps. Achievable technical result - reducing the ripple of the output voltage. The specified result is achieved due to the fact that the power factor corrector contains a diode rectifier, the input pins connected to an electric alternating current network, and the output pins of which are the output pins of the claimed device, a diode and a capacitor. The capacitor is connected to the diode’s cathode by one pin and connected to the negative terminal of the diode rectifier by the other terminal. In this case, a dynistor (uncontrolled thyristor) is inserted into the corrector circuit, connected to the node of the diode’s cathode and the capacitor’s output by the anode, and the diode is connected to the positive anode and the dynistor by the cathode the output of the diode rectifier. 2 ill.

Description

The proposed utility model relates to electrical engineering and can be used in power supply devices for LED lamps and LED lamps.

Currently, there is a rapid development of a new area of technology associated with the use of semiconductor LEDs (LEDs) in lighting. It is important to use traditional electrical networks (alternating voltage 220 V) and traditional forms of lamps and luminaires. As a result, along with the continuous improvement of diabetes, the development of secondary power sources is underway [1-6]. The main goal of these developments is to increase the energy efficiency of LED lamps and systems (increase the power factor), reduce the ripple of the output voltage, filter harmonics, etc.

Known power factor corrector (KKM) [1], powered from an AC voltage network, containing a inductor, three capacitors and a half-wave diode rectifier having two input terminals, positive and negative output terminals. The inductor is connected to the first input terminal of the diode rectifier by one output, the other output of the inductor and the second input terminal of the diode rectifier are KKM input and are connected to the electric network. One terminal of the first capacitor is connected to the positive output terminal of the diode rectifier, the other terminal of the first capacitor is connected to the second input terminal of the diode rectifier. One terminal of the second capacitor is also connected to the second input terminal of the diode rectifier, and the other terminal is connected to the negative output terminal of the diode rectifier. The findings of the third capacitor are connected to the positive and negative output terminals of the diode rectifier and are the output of the power factor corrector.

The disadvantage of this device is the change in output voltage with varying power in the load.

Closest to the claimed utility model is the power factor corrector [2], containing a diode rectifier, three diodes in series according to the included, the first and second capacitors. The cathode of the first diode is connected to the positive, and the anode of the third to the negative terminals of the diode rectifier. The first capacitor is connected with one terminal to the positive terminal of the diode rectifier, and the other terminal is connected to the connection node of the second anode and cathode of the third diode. The second capacitor is connected to the connection node of the anode of the first and the cathode of the second diode with one terminal, and the other terminal is connected to the negative terminal of the diode rectifier. The positive and negative terminals of the rectifier are the output of the corrector and are designed to connect the load.

The disadvantage of the prototype device is the great importance of the ripple of the output voltage.

The task to which the proposed solution is directed is to reduce the output voltage ripple.

The solution to this problem is achieved by the fact that in a CMC containing a diode rectifier, the input terminals are connected to an alternating current electric network, and the output terminals of which are the output terminals of the inventive device, a diode and a capacitor connected to the diode cathode by one output and connected to the negative by another the output of the diode rectifier, introduced a dynistor (uncontrolled thyristor). In this case, the dynistor is connected by an anode to the node connecting the cathode of the diode and the output of the capacitor, and the cathode is connected to the positive terminal of the diode rectifier, and the diode by the anode is connected to the positive terminal of the diode rectifier.

A functional diagram of the device is shown in FIG. 1, on which is indicated: 1 - diode rectifier; 2 - diode; 3 - capacitor; 4 - dinistor, 5 - load resistance.

In FIG. 2 shows a plot of the voltage at the output of the inventive device. T-period of alternating voltage of the electric network.

The device shown in FIG. 1, works as follows. In the time interval from t ₁ to t _{2, the} capacitor 3 is charged through an open diode 2, the voltage on it increases in accordance with the voltage of the supply network. When passing the instantaneous value of the rectified voltage of the maximum value (t ₂ in Fig. 2), the diode 2 is locked, the voltage equal to the maximum value of the rectified voltage at the time t _{2 is} stored on the capacitor 3. Load 5 is supplied with voltage from the output of the diode rectifier.

A subsequent decrease in the instantaneous voltage at the positive terminal of the diode rectifier leads to an increase in the potential difference at the terminals of the dinistor 4. When it reaches the value of the opening voltage of the dinistor (ΔU in Fig. 2) at time t _{3, the} dinistor opens and the capacitor 3 is connected to the load. The diode rectifier is closed and the load 5 is powered by a capacitor 3, discharging it. The voltage across the capacitor 3 decreases. This process continues until the instantaneous voltage value at the positive terminal of the diode rectifier exceeds the residual potential difference of the capacitor 3 (time t ₁ + T / 2 in Fig. 2). Then the described process is periodically repeated.

The introduction of a new element (dinistor) and new inter-element connections into the CMC circuitry demonstrates the novelty of the claimed technical solution.

Experimental studies of a device made according to the circuit shown in FIG. 1, using a diode rectifier type D4S; RSFGL diode; 4.7 uF capacitor 400 V; K1182KP1BP dynistor, load resistance 910 kOhm showed that the ratio of the maximum to the minimum instantaneous voltage value on the load of the inventive device was 1.11, which is 90% less than this indicator for the prototype (2.1). In this case, the power factor is 0.73, i.e., the positive effect of the new technical solution has been proved experimentally.

An additional advantage of the claimed device is the possibility of further reducing the ratio of maximum to minimum voltage at the load by choosing a dynistor with a lower value of the opening voltage.

Sources of information used in the preparation of the description of the utility model:

1. Tverdov I. Passive power factor correctors for single-phase and three-phase power modules // Components and Technologies, 2009. - No. 4. - S. 94-97.

2. Short S. M., A. Lukin Power supplies for LED lighting // Practical Power Electronics, 2012. - No. 2 (46). - S. 3-9. (prototype).

3. Power factor correction device. RF patent 2602415 from 12/11/2006. MPK Н02М 1/12 (2006.01), Н02М 3/335 (2006.01) // Tverdov I.V., Filatiev A.I., Zatulov S.L.

4. Makhlin A. Features of designing a power supply for LED lamps // Semiconductor lighting technology. - 2011. - No. 1. - S. 30-33.

5. Switching power supply for LED lamp. RF patent 164707 dated 03/29/2016. H01L 33/00 (2010.01), Н05В 37/02 (2006.01) // Ivanov A.V. and etc.

6. The connection diagram of the LED light fixture in the AC network. RF patent 2602415 from 06.23.2015. IPC Н05В 37/02 (2006.01) // Tuev V.I. and etc.

Claims (1)

A power factor corrector comprising a diode rectifier, the input terminals connected to an alternating current electric network, and the output terminals of which are output terminals of the inventive device, a diode and capacitor connected to the diode cathode by one output and connected to the negative terminal of the diode rectifier by the other, characterized in that a dynistor (uncontrolled thyristor) is introduced into the corrector circuit, an anode connected to the junction node of the diode and the capacitor output, and a diode anode and a dynistor cathode ohms connected to the positive terminal of the diode rectifier.

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