DE102016121231A1 - LED light control device based on an H-bridge circuit - Google Patents

Abstract

The present invention discloses an H-bridge LED light control device that includes a light control signal module, an LED light source module, a power supply module, and an H-bridge circuit. The LED light source module serves as a load on a common bridge arm in the H bridge circuit and is powered by positive and negative RF pulses. The pulse width of a high frequency module is controlled to realize the effect of double control of light regulation and color regulation. This allows existing products to be easily modified to effectively reduce modifying difficulties and costs.

Description

Field of the invention

The present invention relates to the technical field of LED drives, in particular an LED light control device based on an H-bridge circuit.

State of the art

In total, there are four intercommunication tubes, which are connected in pairs and communicate with each other through a common line. By this connection type and loads on the common line, a structure H-shaped on paper is normally formed. Hence the term "H-bridge" comes. The four interrupters are commonly referred to as bridge arms, and the common common line is commonly referred to as a common bridge arm. H-bridge circuits may be in a common circuit, with bridge arms always maintaining an opposite output on two sides. In this way, the polarity of a load in the presence of a single power supply can be reversed to meet requirements z. B. a motor drive to meet.

As an efficient new light source LED lights have the advantages z. As long life, low energy consumption, energy efficiency and environmental friendliness and are widely used in various areas such as in shopping malls, on the urban streets, in the advertising lighting and vehicle lighting. With the widespread use of LED lighting, ever higher demands are placed on LED lighting technology. Over time, the need has evolved from brightness regulation to color regulation and combinations of several types of regulation. In order not to affect a color temperature shift of an LED, most of the LED illuminators for controlling the brightness and color temperature use PWM (Pulse Width Modulation) mode.

Currently, numerous LED products with brightness and color control functions are commercially available, most of which are controlled by a single cold white type and single warm white type separately or by a common cathode and common anode type. In this way, three or more connection cables are needed between an LED control device and a light plate module. In current similarly wired or polarized lighting, there are only two electrical connection cables, so the color temperature can not be regulated. To regulate the color temperature, an additional electrical connection cable must be added. The result is that the existing product devices must be re-manufactured and at the same time increase the installation difficulties for the consumer.

Problem solving and improvement of the state of the art

It is an object of the present invention to provide an LED lighting control apparatus based on an H-bridge circuit to overcome the shortcomings of the prior art.

In order to eliminate the aforementioned technical defects, the present invention employs the following technical solution: An H-bridge based LED light control device includes a light control signal module, an LED light source module, a power supply module, a first switching unit Q1, a second switching unit Q2, a third one Switching unit Q3 and a fourth switching unit Q4. The first switching unit Q1, the second switching unit Q2, the third switching unit Q3, and the fourth switching unit Q4 form an H bridge circuit, and the LED light source module serves as a load on a common bridge arm in the H bridge circuit.

The light regulation signal module includes a low color temperature carrier frequency circuit, a high color temperature carrier frequency circuit, and a wireless module. The wireless module is each electrically connected to the low color temperature carrier frequency circuit and the high color temperature carrier frequency circuit. The low color temperature carrier frequency circuit and the high color temperature carrier frequency circuit are each electrically connected to the H bridge circuit.

The LED light source module consists of low color temperature LED illuminators and high color temperature LED illuminators that are connected in parallel and the parallel adjacent LED illuminators are connected in opposite directions.

In the above technical solution, the low color temperature carrier frequency circuit and the high color temperature carrier frequency circuit both use a digital-to-analog converter to receive digital signals transmitted from a wireless module and send corresponding frequencies to PWM to control the LED light source module a regulation of the color temperature and brightness is realized.

In the above technical solution, the wireless module is a Bluetooth module that receives Bluetooth signals. The signals convert to digital signals and the digital signals are transmitted to the digital-to-analog converter.

In the above technical solution, the first switching unit Q1, the second switching unit Q2, the third switching unit Q3 and the fourth switching unit Q4 are MOSFET transistors.

In the above technical solution, the voltage stabilizing diodes are connected in parallel between drain electrodes and source electrodes of MOSFET transistors.

In the above technical solution, the low color temperature carrier frequency circuit is connected to each of the grid electrodes of the second switching unit Q2 and the fourth switching unit Q4, while the high color temperature carrier frequency circuit is connected to the grid electrodes of the first switching unit Q1 and the third switching unit Q3, respectively. One end of the LED light source module is connected between the first switching unit Q1 and the third switching unit Q3, and the other end of the LED light source module is connected between the second switching unit Q2 and the fourth switching unit Q4. A positive electrode of the power supply module is connected to drains of the first switching unit Q1 and the second switching unit Q2, and a negative electrode of the power supply module is connected to sources of the third switching unit Q3 and the fourth switching unit Q4.

In the above technical solution, a node between the second switching unit Q2 and the fourth switching unit Q4 is electrically connected to the low-color carrier frequency carrier circuit by a capacitor C5, the capacitor C5 is electrically connected to a diode D2, and is bootstrapped by the diode D2 , A node between the first switching unit Q1 and the third switching unit Q3 is electrically connected to the high color temperature carrier frequency circuit by a capacitor C2, the capacitor C2 is electrically connected to a diode D1, and is bootstrapped by the diode D1, and positive electrodes of the diode Diode D1 and diode D2 are electrically connected to the power supply module.

In the above technical solution, the power supply module is electrically connected to the wireless module through a voltage stabilizer.

In the above technical solution, the power supply module is electrically connected to a polar capacitor C1 and a Schottky diode D3.

The present invention has the following advantageous effects. The LED light source module is powered by positive and negative RF pulses. The pulse width of a high frequency module is controlled to realize the effect of double control of light regulation and color regulation. This allows existing products to be easily modified to effectively reduce modifying difficulties and costs.

Brief description of the drawings

Drawing 1 is a schematic representation of circuits of the present invention.

Drawing 2 is a schematic representation of two frequency PWM of the present invention.

Description of the preferred embodiments

The present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, an H-bridge type LED light control device includes a light regulation signal module, an LED light source module, a power supply module, a first switching unit Q1, a second switching unit Q2, a third switching unit Q3, and a fourth switching unit Q4. The first switching unit Q1, the second switching unit Q2, the third switching unit Q3, and the fourth switching unit Q4 constitute an H-bridge circuit. The LED light source module serves as a load on a common bridge arm in the H bridge circuit.

The light regulation signal module comprises a low color temperature carrier frequency circuit U2, a high color temperature carrier frequency circuit U1, and a wireless module. Each of the wireless module is electrically connected to the low color temperature carrier frequency circuit U2 and the high color temperature carrier frequency circuit U1. The carrier for low color temperature U2 and the carrier for high color temperature U1 are each electrically connected to the H-bridge circuit. The low color temperature carrier frequency circuit and the high color temperature carrier frequency circuit both use a digital-to-analog converter DAC-8 to receive digital signals transmitted from a wireless module and transmit PWM of corresponding frequencies to control the LED light source module Regulation of color temperature and brightness is realized. The PWM of the two frequencies shown in Drawing 2 is used to control the brightness and the color temperature from top to bottom.

The LED light source module consists of low color temperature LED illuminators and high color temperature LED illuminators connected in parallel, and the parallel adjacent LED illuminators are connected in opposite directions. A variety of low color temperature LED lighting and a variety of high color temperature LED lighting can be provided. Single color temperature LED lights are connected in series.

According to the present invention, the wireless module is a Bluetooth module BM-S02 that receives Bluetooth signals. The signals convert to digital signals and the digital signals are transmitted to the digital-to-analog converter DAC-8. The Bluetooth module BM-S02 receives control commands sent by wireless system. Pins 15, 16 of the Bluetooth modules BM-S02 are each electrically connected to a high-frequency carrier frequency pin 2 and a low-temperature carrier frequency pin 2.

According to the present invention, the first switching unit Q1, the second switching unit Q2, the third switching unit Q3 and the fourth switching unit Q4 are MOSFET or BJT transistors. In this embodiment, NMOS transistors are used.

According to the present invention, the voltage stabilizing diodes are connected in parallel between the drains and the source electrodes of the MOSFET transistors. The drains and the source electrodes of the first switching unit Q1, the second switching unit Q2, the third switching unit Q3 and the fourth switching unit Q4 are respectively connected in parallel with resistors R4, R3, R9 and R8.

According to the present invention, the low color temperature carrier frequency circuit is connected to each of grid electrodes of the second switching unit Q2 and the fourth switching unit Q4, while the grid electrode of the second switching unit Q2 is electrically connected through a resistor R1 to a pin 7 of the low color temperature carrier frequency circuit and the grid electrode the fourth switching unit Q4 is electrically connected to a pin 5 of the low-color carrier frequency circuit through a resistor R5. The high color temperature carrier frequency circuit is connected to each of grid electrodes of the first switching unit Q1 and the third switching unit Q3, while the grid electrode of the first switching unit Q1 is electrically connected through a resistor R2 to a pin 7 of the high color temperature carrier frequency circuit and the grid electrode of the third switching unit Q3 is electrically connected by a resistor R6 to a pin 5 of the high frequency color carrier frequency circuit. One end of the LED light source module is connected between the first switching unit Q1 and the third switching unit Q3, while the other end of the LED light source module is connected between the second switching unit Q2 and the fourth switching unit Q4. And a positive electrode of the power supply module is connected to the drains of the first switching unit Q1 and the second switching unit Q2, while a negative electrode of the power supply module is connected to the sources of the third switching unit Q3 and the fourth switching unit Q4.

According to the present invention, a node between the second switching unit Q2 and the fourth switching unit Q4 is electrically connected to the low-color-temperature carrier frequency circuit through a capacitor C5. The capacitor C5 is electrically connected to a negative electrode of a diode D2 and is boosted by the diode D2 by bootstrapping. A node is electrically connected between the first switching unit Q1 and the third switching unit Q3 through a capacitor C2 to the high color temperature carrier frequency circuit. The capacitor C2 is electrically connected to a negative electrode of a diode D1 and is boosted by the diode D1 by bootstrapping. And positive electrodes of the diode D1 and diode D2 are electrically connected to the power supply module.

According to the present invention, the power supply module is electrically connected to the wireless module through a voltage stabilizer HT7533. The input of the voltage stabilizer HT7533 is connected to a resistor R7 and a polar capacitor C6 for filtering, and the output of the voltage stabilizer HT7533 is connected to a capacitor C7 for filtering. The power supply module is electrically connected to a polar capacitor C1 and a Schottky diode D3 for filtering and voltage stabilization. In addition, the power supply module is electrically connected to a fuse F1.

The foregoing embodiments are merely illustrative of the present invention, rather than limiting the present invention. Therefore, equivalent modifications or modifications of the present invention belong to the scope of the application.

Claims (9)

 An LED lighting control apparatus based on an H-bridge circuit, comprising a light regulation signal module, an LED light source module, a power supply module, a first switching unit Q1, a second switching unit Q2, a third switching unit Q3, and a fourth switching unit Q4. The first switching unit Q1, the second switching unit Q2, the third switching unit Q3 and the fourth switching unit Q4 form an H-bridge circuit whose special feature is that the LED light source module serves as a load on a common bridge arm in the H-bridge circuit, wherein the light regulation signal module comprises a low color temperature carrier frequency circuit, a high color temperature carrier frequency circuit, and a wireless module, the wireless module each being electrically connected to the low color temperature carrier frequency circuit and the high color temperature carrier frequency circuit, the low color temperature carrier frequency circuit and the carrier frequency circuit are each electrically connected to the H-bridge circuit for high color temperature, wherein the LED light source module consists of low color temperature LED illuminators and high color temperature LED illuminators connected in parallel and the parallel adjacent LED illuminators are connected in opposite directions. A H-bridge LED light control apparatus according to claim 1, characterized in that the low color temperature carrier frequency circuit and the high color temperature carrier frequency circuit both use a digital-to-analog converter to receive digital signals transmitted from a wireless module and frequencies corresponding to PWM to transmit to control the LED light source module, so that a regulation of the color temperature and brightness is realized. LED lighting control device based on an H-bridge circuit according to claim 2, characterized in that the wireless module is a Bluetooth module that receives Bluetooth signals. The signals convert to digital signals and the digital signals are transmitted to the digital-to-analog converter. LED lighting control device based on an H-bridge circuit according to claim 1, characterized in that the first switching unit Q1, the second switching unit Q2, the third switching unit Q3 and the fourth switching unit Q4 are MOSFET transistors. LED light regulation device based on an H-bridge circuit according to claim 4, characterized in that the voltage stabilization diodes are connected in parallel between drain electrodes and source electrodes of MOSFET transistors. A H-bridge type LED light control device according to claim 4, characterized in that the low color temperature carrier frequency circuit is connected to the grid electrodes of the second switching unit Q2 and the fourth switching unit Q4 respectively, while the high color temperature carrier frequency circuit is connected to the grid electrodes of the first one Switching unit Q1 and third switching unit Q3, one end of the LED light source module is connected between first switching unit Q1 and third switching unit Q3, and the other end of the LED light source module is connected between second switching unit Q2 and fourth switching unit Q4, wherein a positive electrode of the power supply module is connected to drains of the first switching unit Q1 and the second switching unit Q2, and a negative electrode of the power supply module is connected to sources of the third switching unit Q3 and the fourth Sc holding unit Q4 connected. A H-bridge type LED light control device according to claim 5, characterized in that a node between said second switching unit Q2 and said fourth switching unit Q4 is electrically connected to said low-color-temperature carrier frequency circuit by a capacitor C5, said capacitor C5 is electrically connected to a diode D2 is connected and amplified by means of bootstrapping by the diode D2 that a node between the first switching unit Q1 and the third switching unit Q3 is electrically connected by a capacitor C2 to the carrier high-temperature carrier frequency circuit, the capacitor C2 is electrically connected to a diode D1 and is boosted by the diode D1 through bootstrapping, and positive electrodes of the diode D1 and diode D2 are electrically connected to the power supply module. An H-bridge based LED light control device according to claim 1, characterized in that the power supply module is electrically connected to the wireless module by a voltage stabilizer. LED lighting control device based on an H-bridge circuit according to claim 1, characterized in that the Power supply module is electrically connected to a polar capacitor C1 and a Schottky diode D3.

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