DE202017107741U1 - dimming circuit - Google Patents

Abstract

A LED dimming circuit, characterized by comprising: a signal transmission module, a constant current module, wherein the constant current module is connected to the signal transmission module and transmits an electrical signal to the signal transmission module, a signal adjustment module, the signal adaptation module comprising signal control, the feedback signal being transmitted via the signal conditioning module Signal control arrives at the constant current module and controls the constant current module to send an electrical signal therefrom, the signal controller according to the predetermined frequency controls the arrival time of the feedback signal to the constant current module such that the rise and fall of the waveform and the duration of the high and low logic level the electrical signal sent from the constant current module satisfy the predetermined values, a signal receiving module, wherein the signal receiving module is connected to the signal transmission module and a feedback signal whose waveform is equal to the waveform of the e lectric signal is sent to the signal conditioning module.

Description

Field of the invention

The present invention relates to a dimming circuit and more particularly to an LED dimming circuit.

State of the art

People are placing ever-higher demands on quality of life, so LED lighting fixtures, which are most commonly used in everyday life, are becoming more and more sophisticated and the demand for dimmable LED lights is constantly increasing. The existing dimmable LED lamps show that there are many ways to realize the dimming function. In recent years, the DALI protocol has gradually established itself and is thus used more and more frequently in LED dimming circuits.

The DALI protocol is an international standard communication protocol for light control with a transmission rate of 1200 bit / s ± 10%. The DALI protocol is mainly used for the dimming control of several lighting devices. The DALI protocol allows one or more slave units to be controlled by a master unit. A lighting control system operating according to the DALI protocol has the advantages of simple structure, convenient operation and excellent functions. The DALI protocol is thus an important and growing market in the field of intelligent lighting and is becoming increasingly important.

Requirements of the DALI protocol: The rise time and fall time of the signal waves must be between 10 μs to 100 μs and the duration of the high or low logic level of the signal waves must be between 334 μs and 500 μs. Conventional LED dimming circuits have the following problem: when the input voltages 22.5V, -16V and 9.5V are combined with 6.5V, 0V and -6.5V to high and low level signal waves respectively, For example, the rise time and fall time of the waveform of the feedback signal and the duration of the high and low logic levels of the signals can not meet the requirements of the DALI protocol.

Object of the invention

The object of the present invention is to overcome the deficiencies of the prior art and to provide an LED dimming circuit which can precisely control the rise time and fall duration of the waveform while adjusting the duration of the high and low logic levels.

To solve the above technical problem, the present invention provides an LED dimming circuit comprising:
a signal transmission module,
a constant current module, wherein the constant current module is connected to the signal transmission module and sends an electrical signal to the signal transmission module,
a signal conditioning module, the signal conditioning module comprising signal control, the feedback signal arriving at the constant current module via the signal controller and controlling the constant current module to send an electrical signal therefrom, the signal controller controlling the arrival time of the feedback signal at the constant current module according to the predetermined frequency; that the rise and fall of the waveform and the duration of the high and low logic levels of the electrical signal sent by the constant current module meet the predetermined values,
a signal receiving module, wherein the signal receiving module is connected to the signal transmission module and sends a feedback signal whose waveform is equal to the waveform of the electrical signal to the signal conditioning module.

In a preferred embodiment, the invention further comprises a delaying means, wherein the delaying means is connected between the signal receiving module and the signal controller and receives the feedback signal before it enters the signal control to the time required for the feedback signal to enter the signal control delay.

In a preferred embodiment, the signal controller comprises a first switch and a second switch, wherein the delay means is concretely a first delay means and a second delay means, the first delay means being connected between the signal receiving module and the first switch, the second delay means being connected between the signal receiving module and the second switch is switched.

In a preferred embodiment, the first switch is concretely a first transistor Q104 and the second switch is concretely an NMOS transistor Q103 (n-type metal oxide semiconductor NMOS), the gate of the NMOS transistor Q103 being connected to the signal receiving module and the second Delaying means, the drain of the NMOS transistor Q103 being connected to the constant current module, the source of the NMOS transistor Q103 being grounded, the base of the first transistor Q104 being connected to the first delay means and the signal receiving module, the emitter of the first Transistor Q104 is connected between the signal receiving module and the gate of the NMOS transistor Q103, wherein the collector of the first transistor Q104 is grounded.

In a preferred embodiment, the signal receiving module transmits the feedback signal, wherein the base of the first transistor Q104, when the feedback signal is a high level signal, receives the high level signal and disconnects the electrically conductive connection, the gate of the NMOS transistor Q103 receiving the high level signal an electrically conductive connection is established and sends the high level signal to the constant current module, the base of the first transistor Q104, when the feedback signal is a low level signal, receiving the low level signal and establishing an electrically conductive connection therewith, whereby the level of the gate of the NMOS transistor Q103 is lowered and the NMOS transistor Q103, the electrically conductive connection is disconnected.

In a preferred embodiment, the first delay means and the second delay means are each a first capacitance C105 and a second capacitance C110, the first capacitance C105, when the feedback signal is a high level signal, being charged by the high level signal before it enters the first transistor Q104 wherein the high level signal, after fully charging the first capacitance C105, passes through the first transistor Q104 and at the first transistor Q104 the electrically conductive connection is disconnected, simultaneously the high level signal enters the gap of the NMOS transistor Q103 and first charges the second capacitance C110; wherein the high level signal is input to the NMOS transistor Q103 after fully charging the second capacitor C110.

When the feedback signal is a low level signal, the first capacitor C105 is discharged, with the first transistor Q104 receiving the high level signal and disconnecting the electrically conductive connection, the first transistor Q104 not receiving a high level signal after discharging the first capacitance C105, i. H. it is an electrically conductive connection is made, at the same time the second capacitor C110 is discharged, wherein the NMOS transistor Q103 receives the high level signal and in him again an electrically conductive connection is made, the NMOS transistor Q103 after discharging the second capacitor C110 is not receiving a high level signal.

In a preferred embodiment, the constant current module comprises a second transistor Q101 and a third transistor Q102, the base of the second transistor Q101 being connected to the emitter of the third transistor Q102, the collector of the second transistor Q101 being connected to the base of the third transistor Q102 wherein the collector of the third transistor Q102 is connected to the signal transmitting module, the signal matching module being connected between the base of the second transistor Q101 and the emitter of the third transistor Q102.

In a preferred embodiment, in the second transistor Q101, when the drain of the NMOS transistor Q103 sends a high level signal to the base of the second transistor Q101, the electrically conductive connection is disconnected, lowering the level of the base of the third transistor Q102 and the third transistor Q102 an electrically conductive connection is made and the third transistor Q102 sends a high level signal to the signal transmission module, wherein the second transistor Q101, when the drain of the NMOS transistor Q103 does not send a high level signal, an electrically conductive connection is made, wherein the base of the third transistor Q102 receives a high level signal and the third transistor Q102 disconnects the electrically conductive connection and the emitter of the third transistor Q102 sends a low level signal to the signal transmission module.

In a preferred embodiment, the signal transmitting module and the signal receiving module are concretely a first optocoupler PC102 and a second optocoupler PC101 and each connected to a control unit, the constant current module sending an electrical signal to the first optocoupler PC102, the diode side of the first opto-coupler PC102 transmitting the electrical signal receives and converts to an optical signal, wherein the collector-emitter side of the first opto-coupler PC102 receives the optical signal sent from the diode side and converts it into an electrical signal and sends it to the control unit, the control unit sending the electrical signal to the diode side of the second optical coupler Optocoupler PC101 transmits, with the diode side sends the optical signal, the collector-emitter side of the second optocoupler PC101 receives the optical signal and converts it into an electrical signal, i. H. a feedback signal is sent to the signal conditioning module.

In a preferred embodiment, the high and low logic levels sent by the constant current module are kept constant, with the electrical signal being adjusted by the signal conditioning module.

With the technical solution of the present invention, the following advantageous effects are achieved over the prior art:
By charging and discharging the first capacitor and the second capacitor, the switching time of the first transistor and the NMOS transistor is delayed to thereby precisely control the rise time and fall time of the waveform of the feedback signal and the duration of the high and low logic levels, so that the feedback signal regardless of where the input voltage is located, it can meet the requirements of the DALI protocol to ensure that the favorable operating conditions are maintained throughout the lighting system. By setting the two voltages of the base and the emitter of the second transistor and the bias voltage of the third transistor as constant values, the output current of the constant current module can be kept constant.

In the following, the invention will be described in more detail in a schematic representation with reference to the figures. It shows:

1 a circuit diagram of a preferred embodiment according to the present invention,

2 a first schematic representation of the appearance of the product of the preferred embodiment according to the present invention,

3 a second schematic representation of the appearance of the product of the preferred embodiment according to the present invention.

LIST OF REFERENCE NUMBERS

• 1 first switch, 2 second switch, 3 first delay device, 4 second delay device, 5 Constant current module, 6 Signal transmitting module, 7 Receiver module, 8th Driver, 9 Fluorescent light

Detailed description of the embodiment

In order to provide a thorough understanding of the present invention, a preferred embodiment will now be described in detail with reference to the drawings.

An LED dimming circuit comprising:
a signal transmission module,
a constant current module, wherein the constant current module is connected to the signal transmission module and sends an electrical signal to the signal transmission module,
a signal conditioning module, the signal conditioning module comprising signal control, the feedback signal arriving at the constant current module via the signal controller and controlling the constant current module to send an electrical signal therefrom, the signal controller controlling the arrival time of the feedback signal at the constant current module according to the predetermined frequency; that the rise and fall of the waveform and the duration of the high and low logic levels of the electrical signal sent by the constant current module meet the predetermined values,
a signal receiving module, wherein the signal receiving module is connected to the signal transmission module and sends a feedback signal whose waveform is equal to the waveform of the electrical signal to the signal conditioning module.

The present technical solution further comprises a delay device. By the delay means, the arrival time of the feedback signal to the constant current module can be precisely controlled by the signal controller. The delay means is connected between the signal receiving module and the signal controller and receives the feedback signal before it enters the signal control to delay the time required for the feedback signal to enter the signal control.

The signal controller comprises a first switch and a second switch, wherein the delay means is concretely a first delay means and a second delay means, the first delay means being connected between the signal receiving module and the first switch, the second delay means being connected between the signal receiving module and the second switch ,

Please refer 1 , The first switch 1 is in concrete terms a first transistor Q104 and the second switch 2 is a NMOS transistor Q103, wherein the gate of the NMOS transistor Q103 to the signal receiving module 7 and the second delay device 4 wherein the drain of the NMOS transistor Q103 is connected to the constant current module, the source of the NMOS transistor Q103 being grounded, the base of the first transistor Q104 being connected to the first delay means 3 and the signal receiving module 7 is connected, wherein the emitter of the first transistor Q104 between the signal receiving module 7 and the gate of the NMOS transistor Q103 is connected, the collector of the first transistor Q104 being grounded.

The signal receiving module 7 sends the checkback signal, and when the checkback signal is a high level signal, the base of the first transistor Q104 receives the high level signal and disconnects the electrically conductive connection, the gate of the NMOS transistor Q103 receiving the high level signal and establishing an electrically conductive connection and transmitting the high level signal to the constant current module, the base of the first transistor Q104, when the feedback signal is a low level signal, receiving the low level signal and establishing an electrically conductive connection therewith Level of the gate of the NMOS transistor Q103 is lowered and the NMOS transistor Q103, the electrically conductive connection is disconnected.

In order to enable the values of the rise and fall of the waveform and the duration of the high and low logic levels of the feedback signal to satisfy the predetermined values, the first delay means and the second delay means are respectively a first capacitor C105 and a second capacitor C110.

Operating principle: When the feedback signal is a high level signal, the first capacitance C105 is charged from the high level signal before it enters the first transistor Q104, the high level signal passing through the first transistor Q104 after fully charging the first capacitance C105, and the first transistor Q104 electrically conductive connection is disconnected, wherein at the same time the high level signal enters the gap of the NMOS transistor Q103 and first charges the second capacitor C110, wherein the high level signal is received after fully charging the second capacitor C110 in the NMOS transistor Q103.

When the feedback signal is a low level signal, the first capacitor C105 is discharged, with the first transistor Q104 receiving the high level signal and disconnecting the electrically conductive connection, the first transistor Q104 not receiving a high level signal after discharging the first capacitance C105, i. H. it is an electrically conductive connection is made, at the same time the second capacitor C110 is discharged, wherein the NMOS transistor Q103 receives the high level signal and in him again an electrically conductive connection is made, the NMOS transistor Q103 after discharging the second capacitor C110 is not receiving a high level signal. By adjusting the capacitance, the waveform of the feedback signal can be precisely controlled, allowing the feedback signal to meet the requirements of the DALI protocol.

In order to keep the current in the circuit constant, the constant current module comprises a second transistor Q101 and a third transistor Q102, the base of the second transistor Q101 being connected to the emitter of the third transistor Q102, the collector of the second transistor Q101 being connected to the base of the third transistor Q102, the collector of the third transistor Q102 being connected to the signal transmitting module, the signal matching module being connected between the base of the second transistor Q101 and the emitter of the third transistor Q102.

When the drain of the NMOS transistor Q103 sends a high level signal to the base of the second transistor Q101, the second transistor Q101 disconnects the electrically conductive connection, lowering the level of the base of the third transistor Q102 and electrically conductively connecting the third transistor Q102 in the second transistor Q101, when the drain of the NMOS transistor Q103 does not send a high level signal, an electrically conductive connection is established, the base of the third transistor Q102 receives a high level signal and at the third transistor Q102, the electrically conductive connection is disconnected and the emitter of the third transistor Q102 sends a low level signal to the signal transmission module.

The signal transmission module 6 and the signal receiving module 7 Specifically, a first optocoupler PC102 and a second optocoupler PC101 are each connected to a control unit, wherein the constant current module 5 sends an electrical signal to the first photocoupler PC102, wherein the diode side of the first optocoupler PC102 receives the electrical signal and converts it into an optical signal, wherein the collector-emitter side of the first opto-coupler PC102 receives the optical signal sent from the diode side and into converts electrical signal and sends to the control unit, wherein the control unit sends the electrical signal to the diode side of the second optocoupler PC101, the diode side sends the optical signal, wherein the collector-emitter side of the second opto-coupler PC101 receives the optical signal and in a converts electrical signal, ie a feedback signal is sent to the signal conditioning module.

The from the constant current module 5 transmitted high and low logic levels are kept constant, the electrical signal is adjusted by the signal adjustment module to meet the requirements of the DALI protocol.

See the 2 and 3 which are schematic representations of the appearance of the driver formed by the LED dimming circuit according to the invention 8th of the preferred embodiment. The driver 8th is on the surface light 9 attached to drive the surface light.

The above description represents only a preferred embodiment of the invention and is not intended to limit the claims. All equivalent changes and modifications that can be made according to the description and the drawings of the invention by a person skilled in the art fall within the scope of the present invention.

The present invention thus provides a dimming circuit comprising a constant current module, a signal transmission module, a signal receiving module and a signal conditioning module, the constant current module being connected to the signal transmission module and transmitting an electrical signal to the signal transmission module, the signal reception module being connected to the signal transmission module and a feedback signal , the waveform of which is equal to the waveform of the electrical signal, to the signal conditioning module, the signal conditioning module comprising signal control, the feedback signal arriving at the constant current module via the signal controller and controlling the constant current module to send an electrical signal therefrom, the signal controller according to the predetermined frequency controls the arrival time of the feedback signal to the constant current module so that the rise and fall of the waveform and the duration of the high and low logic level of the Konstantstrommodu l send electrical signal meet the predetermined values. With the technical solution according to the invention, the rise time duration and fall time duration of the waveform can be precisely controlled, and simultaneously the duration of the high and low logic levels can be adjusted.

Claims (10)

A LED dimming circuit, characterized by comprising: a signal transmission module, a constant current module, wherein the constant current module is connected to the signal transmission module and transmits an electrical signal to the signal transmission module, a signal adjustment module, the signal adaptation module comprising signal control, the feedback signal being transmitted via the signal conditioning module Signal control arrives at the constant current module and controls the constant current module to send an electrical signal therefrom, the signal controller according to the predetermined frequency controls the arrival time of the feedback signal to the constant current module such that the rise and fall of the waveform and the duration of the high and low logic level the electrical signal sent from the constant current module satisfy the predetermined values, a signal receiving module, wherein the signal receiving module is connected to the signal transmission module and a feedback signal whose waveform is equal to the waveform of the e lectric signal is sent to the signal conditioning module. LED dimming circuit according to claim 1, characterized in that it further comprises a delay means, wherein the delay means is connected between the signal receiving module and the signal control and receives the feedback signal, before it enters the signal control, by the time which the feedback signal for entering needed in the signal control to delay. LED dimming circuit according to claim 2, characterized in that the signal control comprises a first switch and a second switch, wherein the delay means concretely a first delay means and a second delay means, wherein the first delay means between the signal receiving module and the first switch is connected, the second delay means is connected between the signal receiving module and the second switch. LED dimming circuit according to claim 3, characterized in that the first switch is concretely a first transistor Q104 and the second switch is concretely an NMOS transistor Q103, wherein the gate of the NMOS transistor Q103 is connected to the signal receiving module and the second delay means, wherein the drain of the NMOS transistor Q103 is connected to the constant current module, the source of the NMOS transistor Q103 being grounded, the base of the first transistor Q104 being connected to the first delay means and the signal receiving module, the emitter of the first transistor Q104 being between the signal receiving module and the gate of the NMOS transistor Q103 is connected, the collector of the first transistor Q104 being grounded. LED dimming circuit according to claim 4, characterized in that the signal receiving module transmits the feedback signal, wherein the base of the first transistor Q104, when the feedback signal is a high level signal, receives the high level signal and at its the electrically conductive connection is disconnected, wherein the gate of the NMOS Transmitter Q103 receives the high level signal and makes an electrically conductive connection to it and sends the high level signal to the constant current module, the base of the first transistor Q104, when the feedback signal is a low level signal, receiving the low level signal and establishing an electrically conductive connection , whereby the level of the gate of the NMOS Transistor Q103 is lowered and the NMOS transistor Q103 the electrically conductive connection is disconnected. LED dimming circuit according to claim 5, characterized in that the first delay means and the second delay means are each a first capacitor C105 and a second capacitor C110, wherein the first capacitance C105, when the feedback signal is a high level signal from the high level signal before it in the the first transistor Q104 is input, the high level signal after fully charging the first capacitor C105 passes through the first transistor Q104 and the first transistor Q104, the electrically conductive connection is disconnected, while the high-level signal enters the gap of the NMOS transistor Q103 and first charging the second capacitance C110, the high level signal being input to the NMOS transistor Q103 after fully charging the second capacitance C110, the first capacitance C105 being discharged when the feedback signal is a low level signal, the first transistor Q104 being the high level The first transistor Q104, after discharging the first capacitor C105, does not receive a high level signal, ie, it establishes an electrically conductive connection, simultaneously discharging the second capacitance C110, the NMOS Transistor Q103 receives the high level signal and is again made an electrically conductive connection, wherein the NMOS transistor Q103 does not receive a high level signal after discharging the second capacitor C110. LED dimming circuit according to one of claims 4 to 6, characterized in that the constant current module comprises a second transistor Q101 and a third transistor Q102, wherein the base of the second transistor Q101 is connected to the emitter of the third transistor Q102, wherein the collector of the second Transistor Q101 is connected to the base of the third transistor Q102, wherein the collector of the third transistor Q102 is connected to the signal transmission module, wherein the signal matching module between the base of the second transistor Q101 and the emitter of the third transistor Q102 is connected. LED dimming circuit according to claim 7, characterized in that in the second transistor Q101, when the drain of the NMOS transistor Q103 sends a high level signal to the base of the second transistor Q101, the electrically conductive connection is disconnected, wherein the level of the base of the third transistor Q102 is lowered and the third transistor Q102 an electrically conductive connection is made and the third transistor Q102 sends a high level signal to the signal transmission module, wherein the second transistor Q101, when the drain of the NMOS transistor Q103 does not send a high level signal, an electrically conductive connection is made wherein the base of the third transistor Q102 receives a high level signal and the third transistor Q102 disconnects the electrically conductive connection and the emitter of the third transistor Q102 sends a low level signal to the signal transmission module. LED dimming circuit according to claim 1, characterized in that the signal transmission module and the signal receiving module concretely a first optocoupler PC102 and a second optocoupler PC101 and are each connected to a control unit, wherein the constant current module sends an electrical signal to the first optocoupler PC102, wherein the diode side the first optical coupler PC102 receives the electrical signal and converts it into an optical signal, wherein the collector-emitter side of the first optical coupler PC102 receives the optical signal sent from the diode side and converts it into an electrical signal and sends it to the control unit, the control unit sends electrical signal to the diode side of the second optocoupler PC101, wherein the diode side sends the optical signal, wherein the collector-emitter side of the second opto-coupler PC101 receives the optical signal and converts it into an electrical signal, that is, a feedback signal to the Signalanpassungsmo dul sent. LED dimming circuit according to claim 1, characterized in that the high and low logic levels sent from the constant current module are kept constant, wherein the electrical signal is adjusted by the signal adjustment module.

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