CN217643781U - Infrared induction lamp with parameter adjusting function - Google Patents

Abstract

The utility model discloses an infrared induction lamps and lanterns with parameter control function for adjust the parameter of response state, set up circuit and load control circuit including power supply circuit, human detection circuitry, processing circuit, infrared ray receiving circuit, environment light detection circuitry, mode. The utility model discloses an infrared induction lamps and lanterns with parameter control function, it passes through infrared receiving circuit, processing circuit, ambient light detection circuitry and working mode set circuit, send parameter control signal through external remote controller, receive the back by infrared receiving circuit and carry out the regulating parameter through processing circuit, and except that can also set up the dial-up regulation of circuit through working mode through remote controller regulating parameter, dual regulating parameter, it has convenient to use, application scope is wide and security advantage such as high.

Description

Infrared induction lamp with parameter adjusting function

Technical Field

The utility model belongs to the technical field of the infrared induction lamp, concretely relates to infrared induction lamps and lanterns with parameter adjustment function.

Background

Because the society development speed is relatively fast now, so people's standard of living is also constantly improving, and in order to make things convenient for life, many districts have installed infrared induction lamps and lanterns in stair passageway and public area. However, the parameters of the sensing state of the existing lamp cannot be reset after installation. For example, the time length of each lighting of the induction lamp, the induction sensitivity, the induction threshold value of the illumination intensity and the like.

Therefore, the above problems are further improved.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides an infrared induction lamps and lanterns with parameter control function, it passes through infrared receiving circuit, processing circuit, ambient light detection circuitry and working mode set up the circuit, send parameter adjustment signal through external remote controller, receive the back by infrared receiving circuit and carry out adjusting parameter through processing circuit, and can also set up the dial code regulation of circuit through working mode except through remote controller adjusting parameter, dual adjusting parameter, it has convenient to use, application scope is wide and security advantage such as high.

In order to achieve the above object, the utility model provides an infrared induction lamps and lanterns with parameter control function for adjust the parameter of response state (including shell and circuit board, the circuit board is installed in the shell), including power supply circuit, human detection circuitry (heat release electricity), processing circuit, infrared ray receiving circuit, ambient light detection circuitry, mode setting circuit and load control circuit, wherein:

the power supply circuit is electrically connected with the human body detection circuit, the processing circuit, the infrared receiving circuit, the ambient light detection circuit and the load control circuit respectively;

the output end of the human body detection circuit is electrically connected with the detection receiving end of the processing circuit, and the detection output end of the processing circuit is electrically connected with the input end of the load control circuit;

the output end of the ambient light detection circuit is electrically connected with the light receiving end of the processing circuit, the output end of the infrared receiving circuit is electrically connected with the infrared receiving end of the processing circuit, and the working mode setting circuit is electrically connected with the processing circuit.

As a further preferable technical solution of the above technical solution, the ambient light detection circuit includes a light receiving diode D6, the processing circuit includes a processor U4, an anode of the light receiving diode D6 is electrically connected to a pin 18 of the processor U4, the anode of the light receiving diode D6 is further grounded through a capacitor C23, two ends of the capacitor C23 are connected in parallel to a resistor R18, and a cathode of the light receiving diode D6 is connected to a power supply terminal (VDD).

As a further preferable technical solution of the above technical solution, the infrared receiving circuit includes an infrared receiving head IR1, a 3-pin manager of the infrared receiving head IR1 is electrically connected to a 4-pin of the processor U4, one path of the 4-pin of the infrared receiving head IR1 is connected to a power supply terminal (VDD) through a resistor R19, and the other end of the 4-pin of the infrared receiving head IR1 is grounded through a capacitor C24;

the infrared induction lamp with the parameter adjusting function further comprises an infrared remote control indicating circuit, the infrared remote control indicating circuit comprises a light emitting diode DS1, the anode of the light emitting diode DS1 is connected with a power supply end (VDD) through a resistor R21, and the cathode of the light emitting diode DS1 is electrically connected with the 3 pins of the infrared receiving head IR1 through a diode D7.

As a further preferable technical solution of the above technical solution, the operation mode setting circuit includes a dial switch S1, a dial switch S2, and a dial switch S3, wherein:

pin 1 of the dial switch S1 is electrically connected to pin 11 of the processor U4, pin 2 of the dial switch S1 is electrically connected to pin 12 of the processor U4, pin 3 of the dial switch S1 is electrically connected to pin 13 of the processor U4, and pin 4 of the dial switch S1 is electrically connected to pin 14 of the processor U4;

a 5 pin of the dial switch S2 is electrically connected with a 15 pin of the processor U4, a 6 pin of the dial switch S2 is electrically connected with a 16 pin of the processor U4, a 7 pin of the dial switch S2 is electrically connected with a 17 pin of the processor U4, and an 8 pin of the dial switch S2 is electrically connected with a 3 pin of the processor U4;

the 9 pins of the dial switch S3 are electrically connected with the 2 pins of the processor U4, the 10 pins of the dial switch S3 are electrically connected with the 10 pins of the processor U4, the 11 pins of the dial switch S3 are electrically connected with the 9 pins of the processor U4, and the 12 pins of the dial switch S3 are electrically connected with the 8 pins of the processor U4.

As a further preferable technical solution of the above technical solution, the human body detection circuit includes a human body infrared detection end U1, an operational amplifier U2A, and an operational amplifier U2B, wherein:

the output end (2 pin) of the human body infrared detection end U1 is electrically connected with the positive input end of the operational amplifier U2A through a resistor R6, the output end of the operational amplifier U2A is electrically connected with the negative input end of the operational amplifier U2B through a capacitor C8 and a resistor R9 in sequence, and the output end of the operational amplifier U2B is electrically connected with the 19 pin of the processor U4.

As a further preferred technical solution of the above technical solution, the load control circuit includes a relay K1 and a transistor Q1, wherein:

the base electrode of the triode Q1 is electrically connected with the 6 pins of the processor U4 through a resistor R17, and the collector electrode of the triode Q1 is electrically connected with the relay K1 (the relay K1 is connected with the light-emitting lamp).

As a further preferred technical solution of the above technical solution, the power supply circuit includes a power input terminal CON2 and a power management chip U3, wherein:

the power input end CON2 is respectively connected with the live wire end and the zero wire end, and the power input end CON2 is electrically connected with the power management chip U3.

Drawings

Fig. 1 is a processing circuit diagram of the infrared induction lamp with parameter adjusting function of the present invention.

Fig. 2A is an infrared receiving circuit diagram of the infrared induction lamp with parameter adjusting function of the present invention.

Fig. 2B is the circuit diagram of the utility model discloses an infrared remote control indicating circuit and ambient light detection circuit of infrared induction lamps and lanterns with parameter adjustment function.

Fig. 3 is a circuit diagram for setting the operating mode of the infrared induction lamp with parameter adjusting function according to the present invention.

Fig. 4 is a circuit diagram of the load control of the infrared induction lamp with parameter adjusting function of the present invention.

Fig. 5 is a circuit diagram of the infrared sensing lamp with parameter adjusting function for detecting human body.

Fig. 6 is a circuit diagram of the power supply circuit of the infrared induction lamp with parameter adjusting function of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The underlying principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

The utility model discloses an infrared induction lamps and lanterns with parameter adjustment function combines preferred embodiment below, further describes utility model's concrete embodiment.

In the embodiments of the present invention, those skilled in the art will note that the housing, the light emitting lamp, the remote controller, and the like of the present invention can be regarded as the prior art.

Preferred embodiments.

The utility model discloses an infrared induction lamps and lanterns with parameter control function for adjust the parameter of response state (including shell and circuit board, the circuit board is installed in the shell), including power supply circuit, human detection circuitry (heat release electricity), processing circuit, infrared receiving circuit, ambient light detection circuitry, mode setting circuit and load control circuit, wherein:

the power supply circuit is electrically connected with the human body detection circuit, the processing circuit, the infrared receiving circuit, the ambient light detection circuit and the load control circuit respectively;

the output end of the human body detection circuit is electrically connected with the detection receiving end of the processing circuit, and the detection output end of the processing circuit is electrically connected with the input end of the load control circuit;

the output end of the ambient light detection circuit is electrically connected with the light receiving end of the processing circuit, the output end of the infrared receiving circuit is electrically connected with the infrared receiving end of the processing circuit, and the working mode setting circuit is electrically connected with the processing circuit.

Specifically, the ambient light detection circuit includes a light receiving diode D6, the processing circuit includes a processor U4, an anode of the light receiving diode D6 is electrically connected to a pin 18 of the processor U4, the anode of the light receiving diode D6 is further grounded through a capacitor C23, two ends of the capacitor C23 are connected in parallel to a resistor R18, and a cathode of the light receiving diode D6 is connected to a power supply terminal (VDD).

More specifically, the infrared receiving circuit comprises an infrared receiving head IR1, a 3-pin manager of the infrared receiving head IR1 is electrically connected with a 4-pin of the processor U4, the 4-pin of the infrared receiving head IR1 is connected with a power supply end (VDD) through a resistor R19 in one way, and the other end of the 4-pin of the infrared receiving head IR1 is grounded through a capacitor C24;

the infrared induction lamp with the parameter adjusting function further comprises an infrared remote control indicating circuit, the infrared remote control indicating circuit comprises a light emitting diode DS1, the anode of the light emitting diode DS1 is connected with a power supply end (VDD) through a resistor R21, and the cathode of the light emitting diode DS1 is electrically connected with the 3 pins of the infrared receiving head IR1 through a diode D7.

Further, the working mode setting circuit comprises a dial switch S1, a dial switch S2 and a dial switch S3, wherein:

pin 1 of the dial switch S1 is electrically connected to pin 11 of the processor U4, pin 2 of the dial switch S1 is electrically connected to pin 12 of the processor U4, pin 3 of the dial switch S1 is electrically connected to pin 13 of the processor U4, and pin 4 of the dial switch S1 is electrically connected to pin 14 of the processor U4;

a 5 pin of the dial switch S2 is electrically connected with a 15 pin of the processor U4, a 6 pin of the dial switch S2 is electrically connected with a 16 pin of the processor U4, a 7 pin of the dial switch S2 is electrically connected with a 17 pin of the processor U4, and an 8 pin of the dial switch S2 is electrically connected with a 3 pin of the processor U4;

the 9 th pin of the dial switch S3 is electrically connected with the 2 nd pin of the processor U4, the 10 th pin of the dial switch S3 is electrically connected with the 10 th pin of the processor U4, the 11 th pin of the dial switch S3 is electrically connected with the 9 th pin of the processor U4, and the 12 th pin of the dial switch S3 is electrically connected with the 8 th pin of the processor U4.

Furthermore, the human body detection circuit comprises a human body infrared detection end U1, an operational amplifier U2A and an operational amplifier U2B, wherein:

the output end (2 pins) of the human body infrared detection end U1 is electrically connected with the positive input end of the operational amplifier U2A through a resistor R6, the output end of the operational amplifier U2A is electrically connected with the negative input end of the operational amplifier U2B through a capacitor C8 and a resistor R9 in sequence, and the output end of the operational amplifier U2B is electrically connected with the 19 pins of the processor U4.

Preferably, the load control circuit includes a relay K1 and a transistor Q1, wherein:

the base electrode of the triode Q1 is electrically connected with the 6 pins of the processor U4 through a resistor R17, and the collector electrode of the triode Q1 is electrically connected with the relay K1 (the relay K1 is connected with the light-emitting lamp).

Preferably, the load control circuit includes a relay K1 and a transistor Q1, wherein:

the base electrode of the triode Q1 is electrically connected with the 6 pins of the processor U4 through a resistor R17, and the collector electrode of the triode Q1 is electrically connected with the relay K1 (the relay K1 is connected with the light-emitting lamp).

The principle of the utility model is that:

in the traditional infrared induction lamp, after the human body detection circuit detects the infrared ray of the human body, a signal is transmitted to the processing circuit, then the processing circuit drives the load control circuit to drive the luminescent lamp to light, but the specific lighting time, the human body infrared detection sensitivity and the intensity of the ambient light (sometimes, the lamp is started when the day is not completely black, but the lamp is started when the light is weak) are all unadjustable;

the utility model discloses an aspect is received the regulation instruction that the remote controller sent through infrared ray receiving circuit, then with adjusting parameter's data transmission to processing circuit, processing circuit carries out the parameter control, and on the other hand sets up the dial-up regulation that the circuit carried out manual form through operating mode, including three dial-up switch, the corresponding threshold value of lighting up time length, sensitivity and illumination intensity is adjusted, and treater U1 has programmable function.

It is worth mentioning that the technical features such as the shell, the light emitting lamp and the remote controller that the patent application relates to should be regarded as prior art, and the specific structure, the theory of operation and the control mode that may involve, the spatial arrangement mode of these technical features adopt the conventional selection in this field can, should not be regarded as the invention point of the utility model discloses a do not further specifically expand the detailed description.

It will be apparent to those skilled in the art that modifications and variations can be made in the above-described embodiments, or some features of the invention may be substituted or omitted, and any modification, substitution, or improvement made within the spirit and principle of the present invention shall fall within the protection scope of the present invention.

Claims (7)

1. The utility model provides an infrared induction lamps and lanterns with parameter adjustment function for adjust the parameter of response state, its characterized in that, including power supply circuit, human detection circuitry, processing circuit, infrared ray receiving circuit, ambient light detection circuitry, mode setting circuit and load control circuit, wherein:

the power supply circuit is electrically connected with the human body detection circuit, the processing circuit, the infrared receiving circuit, the ambient light detection circuit and the load control circuit respectively;

the output end of the human body detection circuit is electrically connected with the detection receiving end of the processing circuit, and the detection output end of the processing circuit is electrically connected with the input end of the load control circuit;

the output end of the ambient light detection circuit is electrically connected with the light receiving end of the processing circuit, the output end of the infrared receiving circuit is electrically connected with the infrared receiving end of the processing circuit, and the working mode setting circuit is electrically connected with the processing circuit.

2. The ir-sensing lamp with parameter adjustment function according to claim 1, wherein the ambient light detection circuit comprises a light receiving diode D6, the processing circuit comprises a processor U4, an anode of the light receiving diode D6 is electrically connected to pin 18 of the processor U4, an anode of the light receiving diode D6 is further connected to ground through a capacitor C23, a resistor R18 is connected in parallel to two ends of the capacitor C23, and a cathode of the light receiving diode D6 is connected to a power supply terminal.

3. The lamp as claimed in claim 2, wherein the IR receiving circuit comprises an IR receiving head IR1, the 3 butler of the IR receiving head IR1 is electrically connected to the 4 pins of the processor U4, the 4 pins of the IR receiving head IR1 are connected to a power source through a resistor R19 on one path and the other end of the 4 pins of the IR receiving head IR1 is grounded through a capacitor C24 on the other path;

the infrared induction lamp with the parameter adjusting function further comprises an infrared remote control indicating circuit, the infrared remote control indicating circuit comprises a light emitting diode DS1, the anode of the light emitting diode DS1 is connected with a power supply end through a resistor R21, and the cathode of the light emitting diode DS1 is electrically connected with the 3 pins of the infrared receiving head IR1 through a diode D7.

4. The infrared induction lamp with the parameter adjusting function as claimed in claim 3, wherein the operation mode setting circuit comprises a dial switch S1, a dial switch S2 and a dial switch S3, wherein:

pin 1 of the dial switch S1 is electrically connected to pin 11 of the processor U4, pin 2 of the dial switch S1 is electrically connected to pin 12 of the processor U4, pin 3 of the dial switch S1 is electrically connected to pin 13 of the processor U4, and pin 4 of the dial switch S1 is electrically connected to pin 14 of the processor U4;

a 5 pin of the dial switch S2 is electrically connected with a 15 pin of the processor U4, a 6 pin of the dial switch S2 is electrically connected with a 16 pin of the processor U4, a 7 pin of the dial switch S2 is electrically connected with a 17 pin of the processor U4, and an 8 pin of the dial switch S2 is electrically connected with a 3 pin of the processor U4;

the 9 pins of the dial switch S3 are electrically connected with the 2 pins of the processor U4, the 10 pins of the dial switch S3 are electrically connected with the 10 pins of the processor U4, the 11 pins of the dial switch S3 are electrically connected with the 9 pins of the processor U4, and the 12 pins of the dial switch S3 are electrically connected with the 8 pins of the processor U4.

5. The infrared induction lamp with the parameter adjusting function according to claim 4, wherein the human body detection circuit comprises a human body infrared detection end U1, an operational amplifier U2A and an operational amplifier U2B, wherein:

the output end of the human body infrared detection end U1 is electrically connected with the positive input end of the operational amplifier U2A through a resistor R6, the output end of the operational amplifier U2A is electrically connected with the negative input end of the operational amplifier U2B through a capacitor C8 and a resistor R9 in sequence, and the output end of the operational amplifier U2B is electrically connected with the 19-pin of the processor U4.

6. The IR induction lamp with parameter adjusting function according to claim 5, wherein the load control circuit comprises a relay K1 and a transistor Q1, wherein:

the base electrode of the triode Q1 is electrically connected with the 6 pins of the processor U4 through a resistor R17, and the collector electrode of the triode Q1 is electrically connected with the relay K1.

7. The IR induction lamp with parameter adjusting function according to claim 6, wherein the power supply circuit comprises a power input CON2 and a power management chip U3, wherein:

the power input end CON2 is respectively connected with a fire wire end and a zero wire end, and the power input end CON2 is electrically connected with the power management chip U3.

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