DE202016101940U1 - 2-way two-line lighting circuit - Google Patents

Abstract

A 2-way, two-line lighting circuit including an insulated switching power supply module A / D, a full-bridge drive circuit module and a light control module, characterized in that the full-bridge drive circuit module consists of the transistors Q2-Q5. The two transistors Q2 and Q4 are first connected in series. Subsequently, these series circuits are connected in parallel with the transistors Q3 and Q5, respectively. The two ground electrodes of the transistor Q4 are connected to the resistors R15 and R16. The two base electrodes of the transistor Q5 are connected to the resistors R14 and R17. The other side of the resistor R15, the emitter of the transistor Q4, the other side of the resistor R14 and the emitter of the transistor Q5 are connected to the high voltage line HV. The two sides of the high voltage line HV are respectively high voltage input INPUT and high voltage output OUTPUT. The other side of the resistor R16 and the collecting electrode of the transistor Q5 are connected to the output OU2 of the LED2. The other side of the resistor R17 and the collecting electrode of the transistor Q4 are connected to the output OU1 of the LED1. The positive and negative leads of the LED series are respectively connected to the output side OU1 of LED1 and the output side OU2 of LED2. This controls the two-line lighting circuit. The common electrode of the transistor Q2 is connected in series with the resistor R19, then this series circuit is connected to the 5th comparator of the microcontroller U2. The collecting electrode of the transistor Q3 is connected in series with the resistor R18, then this series circuit is connected to the 6th comparator of the microcontroller U2. The radiators of transistors Q2 and Q3 are grounded at the same time. The input INPUT of the high voltage line HV is connected to the output coil of the transformer T1. The input of the transformer T1 is connected to the isolated switching power supply module A / D. Between the output coil of the transformer T1 and the full-bridge driver circuit module, the capacitors C3 and C4 are connected in parallel. The other sides of the capacitor C3 and capacitor C4 are connected to the high voltage line HV. The high voltage power HV is connected to the diode D7. Both sides of the diode D7 are connected in parallel with the capacitor C8 and capacitor C9. The light control module includes a microcontroller U2. The fourth comparator of the microcontroller U2 is connected to one side of the switch SW1. The other side of switch SW1 is grounded. The diode ZD1 and the capacitor C9 are connected in parallel. The parallel circuit is connected to the 8th comparator of the microcontroller U2. The other side of the parallel circuit is connected to the resistor R10. The other side of the resistor R10 is connected to the high voltage line HV.

Description

Technical part

This new type refers to a control circuit for a 2-way two-line lighting circuit

Background information

The existing control circuits for 2-way, two-line lighting circuits are often switched off because of the excessive load. But this switch-off takes a negative influence on the lighting equipment such as street lamps and the like. In addition, the single-chip microcontroller could be reset due to these failures, causing the time control to go crazy. That in turn is dangerous.

Content of the utility model

The intended purpose of this utility model is to provide a 2-way, two-line lighting circuit to provide a high-resolution solution to the above.

To meet the above purpose, the following technical concept is provided:
A two-way, two-line lighting circuit including an insulated switching power supply module A / D, a full-bridge drive circuit module and a light control module, characterized in that the full-bridge drive circuit module consists of the transistors Q2-Q5. The two transistors Q2 and Q4 are first connected in series. Subsequently, these series circuits are respectively connected in parallel with the transistors Q3 and Q5. The two ground electrodes of the transistor Q4 are connected to the resistors R15 and R16. The two base electrodes of the transistor Q5 are connected to the resistors R14 and R17. The other side of the resistor R15, the emitter of the transistor Q4, the other side of the resistor R14 and the emitter of the transistor Q5 are connected to the high voltage line HV. The two sides of the high voltage line HV are respectively high voltage input INPUT and high voltage output OUTPUT. The other side of the resistor R16 and the collecting electrode of the transistor Q5 are connected to the output OU2 of the LED2. The other side of the resistor R17 and the collecting electrode of the transistor Q4 are connected to the output OU1 of the LED1. The positive and negative leads of the LED series are respectively connected to the output side OU1 of LED1 and the output side OU2 of LED2. This controls the two-line lighting circuit. The common electrode of the transistor Q2 is connected in series with the resistor R19, then this series circuit is connected to the 5th comparator of the microcontroller U2. The collecting electrode of the transistor Q3 is connected in series with the resistor R18, then this series circuit is connected to the 6th comparator of the microcontroller U2. The radiators of transistors Q2 and Q3 are grounded at the same time. The input INPUT of the high voltage line HV is connected to the output coil of the transformer T1. The input of the transformer T1 is connected to the isolated switching power supply module A / D. Between the output coil of the transformer T1 and the full-bridge driver circuit module, the capacitors C3 and C4 are connected in parallel. The other sides of the capacitor C3 and capacitor C4 are connected to the high voltage line HV. The high voltage power HV is connected to the diode D7. Both sides of diode D7 are connected in parallel with capacitor C8 and resistor R9C9. The light control module includes a microcontroller U2. The fourth comparator of the microcontroller U2 is connected to one side of the switch SW1. The other side of switch SW1 is grounded. The diode ZD1 and the capacitor C9 are connected in parallel. The parallel circuit is connected to the 8th comparator of the microcontroller U2. The other side of the parallel circuit is connected to the resistor R10. The other side of the resistor R10 is connected to the high voltage line HV.

The concept of this utility model is that the second comparator of the microcontroller U2, the resistor R11 and CDS1 are connected in series and this series connection with the third comparator of the microcontroller U2. The second comparator and the third comparator of the microcontroller U2 are respectively connected to the capacitor C12 (R12) and C13 (R13). The other side of capacitors C12 (R12) and C13 (R13) are grounded. The resistor R11 is zero resistance. The capacitor C12 has a capacity of 15 PF and the capacitor C13 has a capacity of 20 PF.

The concept of this utility model is that the first comparator of the microcontroller U2, the resistor R20, photodiode or photoresistor CDS1 are connected in series. And this series connection is connected to the 3rd comparator of the microcontroller U2. The second comparator of microcontroller U2 is first connected to resistor R13 and then grounded. The photodiode or the photoresistor CDS1 and switch SW1 are grounded. The resistor R20 is zero resistance. The resistance values of R12 and R13 are from 5 kohms to 100 kohms.

The concept of this utility model is that the 1st and 2nd comparators of microcontroller U2 are respectively connected through resistor R20 and R13 are connected to the positive pole of the photodiode or the photoresistor CDS1. And the negative pole of the photodiode or the photoresistor CDS1 is connected to the third comparator of the microcontroller U2. Then the negative pole and resistor R12 are connected in series. The resistor R20 is zero resistance. The resistance values of R12 and R13 are from 5 kohms to 100 kohms.

In comparison with the existing technology, the utility model has the following positive effects: In this utility model, the switching power supply and the controller are housed on a single circuit board and with the help of the output voltage of the full bridge driver circuit module, the LED series operates by the positive and negative output voltage changes of the four transtors that are controlled by the microcontroller. The LED strips of main line and anti-line (2-way 2-line lighting circuit) can save a copper wire compared to making a 2-way 3-line lighting circuit. We can integrate the controller and the power supply to save energy.

drawings

: General plan for the utility model

: Circuit diagram for the time control function with the crystal oscillator in this utility model

: Circuit diagram for the function of the time control and the light control in this pattern

: Schematic for the function of the light control in this pattern

Detailed description

In the following, the technical design of the utility model is clearly and completely described with the aid of the drawings. The description mentioned in this article is of course only part of the whole. All other utility models developed by ordinary technicians on the basis of our utility model, the practical, new type, without innovative work, are under the protection of this new, practical model.

Please refer - The utility model relates to a two-way, two-line lighting circuit including an isolated switching power supply module A / D, a full-bridge driver circuit module and a light control module. The full-bridge driver circuit module consists of transistors Q2-Q5. The two transistors Q2 and Q4 are first connected in series. Subsequently, this series connection is connected in parallel with the transistors Q3 and Q5, respectively. The two ground electrodes of the transistor Q4 are connected to the resistors R15 and R16. The two base electrodes of the transistor Q5 are connected to the resistors R14 and R17. The other side of the resistor R15, the emitter of the transistor Q4, the other side of the resistor R14 and the emitter of the transistor Q5 are connected to the high voltage line HV. The two sides of the high voltage power HV are respectively connected to the high voltage input INPUT and high voltage output OUT. The other side of the resistor R16 and the collector of the transistor Q5 are connected to the output OU2 of the LED2. The other side of the resistor R17 and the common electrode of the transistor Q4 are connected to the output OU1 of the LED1. The positive and negative leads of the LED series are respectively connected to the output side OU1 of LED1 and the output side OU2 of LED2. This controls the two-line lighting circuit. The common electrode of the transistor Q2 is connected in series with the resistor R19, and then this series circuit is connected to the 5th comparator of the microcontroller U2. The collecting electrode of the transistor Q3 is connected in series with the resistor R18, and then this series circuit is connected to the 6th comparator of the microcontroller U2. The radiators of transistors Q2 and Q3 are grounded at the same time. When opening and closing the LED series, the voltage is stable thanks to the full-bridge driver circuit module. The circuit is protected.

The input INPUT of the high voltage line HV is connected to the output coil of the transformer T1. The input of the transformer T1 is connected to the isolated switching power supply module A / D. The isolated switching power supply module A / D belongs to the existing technology. That's why it will not be described here. Between the output coil of the transformer T1 and the full-bridge driver circuit module, the capacitors C3 and C4 are connected in parallel. The other sides of the capacitor C3 and capacitor C4 are connected to the high voltage line HV. The high voltage power HV is connected to the diode D7. Both sides of the diode D7 are connected in parallel with the capacitor C8 and capacitor C9. The noise suppression of the capacitor C3 and C4 prevents the disturbances of the control circuit.

The light control module includes a microcontroller U2. The fourth comparator of the microcontroller U2 is connected to one side of the switch SW1. The other side of switch SW1 is grounded. The diode ZD1 and the capacitor C9 are connected in parallel. The parallel circuit is connected to the 8th comparator of the microcontroller U2. The other side of the parallel circuit is connected to the resistor R10. The other side of the resistor R10 is connected to the high voltage line HV, and supplies power to the microcontroller U2. By the Zener diode ZD1 the operation of the microcontroller U2 is stable.

The second comparator of the microcontroller U2, the resistor R11 and CDS1 are connected in series and this series circuit with the 3rd comparator of the microcontroller U2. The second comparator and the third comparator of the microcontroller U2 are respectively connected to the capacitor C12 (R12) and C13 (R13). The other side of capacitors C12 (R12) and C13 (R13) are grounded. The resistor R11 is zero resistance. Capacitor C12 has a capacitance of 15 pF and capacitor C13 has a capacitance of 20 pF.

The first comparator of the microcontroller U2, the resistor R20, photodiode or photoresistor CDS1 are connected in series. And this series connection is connected to the 3rd comparator of the microcontroller U2. The second comparator of microcontroller U2 is first connected to resistor R13 and then grounded. The photodiode or the photoresistor CDS1 and switch SW1 are grounded. The resistor R20 is zero resistance. The resistance values of R12 and R13 are from 5 kohms to 100 kohms. This achieves a light control system which turns on the light for 8 hours and turns off the circuit for 14 hours, 2 hours induction for the light-time control module cycle.

The first and second comparators of the microcontroller U2 are respectively connected through the resistor R20 and R13 to the positive pole of the photodiode or the photoresistor CDS1. And the negative pole of the photodiode or the photoresistor CDS1 is connected to the third comparator of the microcontroller U2. Then the negative pole and resistor R12 are connected in series. The resistor R20 is zero resistance. The resistance values of R12 and R13 are between 5 kOhm and 100 kOhm, which ensures the function of the light control.

For the technicians of this field, this utility model is not limited to the details mentioned above. Therefore, this utility model should not be considered as a limited pattern but as an example. This means that alternative comparators could only use in this utility model if they are, according to the claims, alternative comparators. Also, all drawings of this utility model are not to be considered as limited claims.

In addition, it should be understood that the product description is based on the utility model, but not every utility model contains only a single, technical concept. The way of describing the product description is only due to the clarity. Technicians in the field should consider the instructions for use as a whole. The technical concepts in the utility models may, through certain combinations, produce other utility models that the technicians of the art can understand.

Claims (4)

A two-way, two-line lighting circuit including an insulated switching power supply module A / D, a full-bridge drive circuit module and a light control module, characterized in that the full-bridge drive circuit module consists of the transistors Q2-Q5. The two transistors Q2 and Q4 are first connected in series. Subsequently, these series circuits are connected in parallel with the transistors Q3 and Q5, respectively. The two ground electrodes of the transistor Q4 are connected to the resistors R15 and R16. The two base electrodes of the transistor Q5 are connected to the resistors R14 and R17. The other side of the resistor R15, the emitter of the transistor Q4, the other side of the resistor R14 and the emitter of the transistor Q5 are connected to the high voltage line HV. The two sides of the high voltage line HV are respectively high voltage input INPUT and high voltage output OUTPUT. The other side of the resistor R16 and the collecting electrode of the transistor Q5 are connected to the output OU2 of the LED2. The other side of the resistor R17 and the collecting electrode of the transistor Q4 are connected to the output OU1 of the LED1. The positive and negative leads of the LED series are respectively connected to the output side OU1 of LED1 and the output side OU2 of LED2. This controls the two-line lighting circuit. The common electrode of the transistor Q2 is connected in series with the resistor R19, then this series circuit is connected to the 5th comparator of the microcontroller U2. The collecting electrode of the transistor Q3 is connected in series with the resistor R18, then this series circuit is connected to the 6th comparator of the microcontroller U2. The radiators of transistors Q2 and Q3 are grounded at the same time. The input INPUT of the high voltage line HV is connected to the output coil of the transformer T1. The input of the transformer T1 is connected to the isolated switching power supply module A / D. Between the output coil of the transformer T1 and the full-bridge driver circuit module, the capacitors C3 and C4 are connected in parallel. The other sides of the capacitor C3 and capacitor C4 are connected to the high voltage line HV connected. The high voltage power HV is connected to the diode D7. Both sides of the diode D7 are connected in parallel with the capacitor C8 and capacitor C9. The light control module includes a microcontroller U2. The fourth comparator of the microcontroller U2 is connected to one side of the switch SW1. The other side of switch SW1 is grounded. The diode ZD1 and the capacitor C9 are connected in parallel. The parallel circuit is connected to the 8th comparator of the microcontroller U2. The other side of the parallel circuit is connected to the resistor R10. The other side of the resistor R10 is connected to the high voltage line HV. The 2-way two-line lighting circuit according to claim 1, characterized in that the second comparator of the microcontroller U2, the resistor R11 and CDS1 are connected in series and this series connection with the 3rd comparator of the microcontroller U2. The second comparator and the third comparator of the microcontroller U2 are respectively connected to the capacitor C12 (R12) and C13 (R13). The other side of capacitors C12 (R12) and C13 (R13) are grounded. The resistor R11 is zero resistance. The capacitor C12 has a capacity of 15 PF and the capacitor C13 has a capacity of 20 PF. The 2-way two-line lighting circuit according to claim 1, characterized in that the first comparator of the microcontroller U2, the resistor R20, photodiode or photoresistor CDS1 are connected in series. And this series connection is connected to the 3rd comparator of the microcontroller U2. The second comparator of microcontroller U2 is first connected to resistor R13 and then grounded. The photodiode or the photoresistor CDS1 and switch SW1 are grounded. The resistor R20 is zero resistance. The resistance values of R12 and R13 are from 5 kohms to 100 kohms. The 2-way two-line lighting circuit according to claim 1, characterized in that the 1st and 2nd comparator of the microcontroller U2 are respectively connected through the resistor R20 and R13 to the positive pole of the photodiode or the photoresistor CDS1. And the negative pole of the photodiode or the photoresistor CDS1 is connected to the third comparator of the microcontroller U2. Then the negative pole and resistor R12 are connected in series. The resistor R20 is zero resistance. The resistance values of R12 and R13 are from 5 kohms to 100 kohms.

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