CN102176800B - Low-power consumption infrared sensing controller - Google Patents
Low-power consumption infrared sensing controller Download PDFInfo
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- CN102176800B CN102176800B CN 201110020212 CN201110020212A CN102176800B CN 102176800 B CN102176800 B CN 102176800B CN 201110020212 CN201110020212 CN 201110020212 CN 201110020212 A CN201110020212 A CN 201110020212A CN 102176800 B CN102176800 B CN 102176800B
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Abstract
The invention relates to a low-power consumption infrared sensing controller which comprises an infrared signal detecting and amplifying circuit, a single chip control circuit, a relay driving circuit and a step-down rectifying circuit, wherein the infrared signal detecting and amplifying circuit comprises an infrared sensor and a signal amplifying circuit thereof; the single chip control circuitcomprises a single chip; the relay driving circuit comprises a relay; the step-down rectifying circuit comprises a first step-down rectifying branch and a second step-down rectifying branch; the first step-down rectifying branch converts alternating current into direct current, and supplies the direct current to the infrared signal detecting and amplifying circuit and the single chip control circuit; the second step-down rectifying branch converts alternating current into direct current, and supplies the direct current to the relay driving circuit; when the relay is switched off, the second step-down rectifying branch is in an open-circuit state; the infrared sensor amplifies the detected signal through the signal amplifying circuit and sends the amplified signal to the single chip; and the single chip sends a signal to control the on/off of the relay. Compared with the prior art, the infrared sensing controller provided by the invention is low in power consumption and cost.
Description
Technical field
The present invention relates to a kind of infrared induction controller, especially relate to a kind of low-power-consumption infrared induction controller.
Background technology
Infrared induction controller be usually used in the throwing light on control of the luminophor power switch in the control field.At present, main infrared induction controller adopts capacity voltage dropping circuit to be used as step-down rectifying circuit mostly.See also Fig. 1, it is step-down rectifier and the on-off circuit schematic diagram of prior art infrared induction controller.This step-down rectifier and on-off circuit comprise the reduction voltage circuit 10 that is comprised of capacitor C 1, resistance R 1, R2, the bridge rectifier circuit 11 that is comprised of diode D1, D2, D3 and D4 and the on-off circuit 12 that is comprised of relay K 1 and diode D8.AC power sends the circuit such as infrared induction controller amplifying circuit, single-chip microcomputer (not shown) through reduction voltage circuit 10 and rectification circuit 11 step-down rectifiers to after by voltage stabilizing diode ZD1 and integrated three-terminal regulator IC1 voltage stabilizing.Single-chip microcomputer is according to the power on/off of passing through a triode Q2 pilot relay K1 after the infrared signal analyzing and processing that detects, thus the Push And Release of control luminophor.Because the On current of this relay K 1 generally is about 20mA, when the AC power work of 220V, the capacitance that must make capacitor C 1 is that 0.47 μ F is as decompression capacitor.Like this, because the electric capacity of capacitor C 1 is larger, when relay K 1 disconnected, unnecessary electric current just ran off by voltage stabilizing diode ZD1, no matter and relay whether the power consumption of this step-down rectifier of conducting and on-off circuit all can reach more than the 0.7W.
In addition, in order to reduce the power consumption of infrared induction controller, mostly adopt at present the circuit structure of impulse-type relay and resistance step-down.Because as long as paired pulses formula relay applies pulse current and can make its conducting or disconnection, in the occasion that does not need frequent switch luminophor, use time pulse relay can reduce circuit power consumption, its quiescent dissipation is about 0.1W.But, because the time pulse relay price is 10 to 20 times of common relay, adopt time pulse relay higher as the cost of the gauge tap of infrared induction controller, greatly limited it and used and promote.
Summary of the invention
The object of the invention is to overcome shortcoming of the prior art with not enough, a kind of cheaply low-power-consumption infrared induction controller is provided.
The present invention is achieved by the following technical solutions: a kind of low-power-consumption infrared induction controller, comprise that an infrared signal detects and amplifying circuit, and it comprises an infrared inductor and signal amplification circuit thereof; One single chip machine controlling circuit, it comprises a single-chip microcomputer; One relay drive circuit, it comprises a relay; An and step-down rectifying circuit, it comprises the first step-down rectifier branch road and the second step-down rectifier branch road, this the first step-down rectifier branch road offers this infrared signal detection and amplifying circuit and single chip machine controlling circuit after alternating current is converted to direct current, this the second step-down rectifier branch road offers this relay drive circuit after alternating current is converted to direct current, when this relay disconnected, this second step-down rectifier branch road was off state; This infrared inductor is sent to single-chip microcomputer with the signal that detects after signal amplification circuit amplifies, single-chip microcomputer sends adhesive and the disconnection of signal control relay.
With respect to prior art, the step-down rectifying circuit of infrared induction controller of the present invention comprises respectively two step-down rectifier branch roads, one of them step-down rectifier branch road provides direct supply for each functional circuit, another step-down rectifier branch road provides direct supply for relay specially, then when relay disconnects, open circuit simultaneously for this relay provides the step-down rectifier branch road of direct supply, thereby this branch road does not consume extra power, reached the effect that reduces the infrared induction controller power consumption.
In order to understand more clearly the present invention, set forth the specific embodiment of the present invention below with reference to description of drawings.
Description of drawings
Fig. 1 is step-down rectifier and the on-off circuit schematic diagram of prior art infrared induction controller.
Fig. 2 is the structured flowchart of infrared induction controller 20 of the present invention.
Fig. 3 is the circuit theory diagrams of infrared induction controller of the present invention.
Embodiment
Please consult simultaneously Fig. 2 and Fig. 3, Fig. 2 is the structured flowchart of infrared induction controller 20 of the present invention, and Fig. 3 is physical circuit schematic diagram shown in Figure 2.Infrared induction controller 20 of the present invention comprises that step-down rectifying circuit 21, mu balanced circuit 22, single chip machine controlling circuit 23, lighting time regulating circuit 24, sensitivity adjusting circuit 25, ambient brightness regulating circuit 26, LED indicating circuit 27, infrared signal detect and amplifying circuit 28 and relay drive circuit 29.Relay K 1 control in the relay drive circuit 29 is serially connected in the light on and off of the load electric light 30 in the AC power.AC power is through providing the DC voltage of 12V behind the step-down rectifying circuit 21, this DC voltage offers single chip machine controlling circuit 23, lighting time regulating circuit 24, sensitivity adjusting circuit 25, ambient brightness regulating circuit 26, LED indicating circuit 27 after through mu balanced circuit 22 voltage stabilizings, infrared signal detects and amplifying circuit 28 and relay drive circuit 29 as stable dc power supply.Lighting time regulating circuit 24, sensitivity adjusting circuit 25, ambient brightness regulating circuit 26, LED indicating circuit 27, infrared signal detects and amplifying circuit 28 and relay drive circuit 29 access respectively each pin of the single-chip microcomputer 231 in the single chip machine controlling circuit 23.
Particularly, this step-down rectifying circuit 21 comprises the first step-down rectifier branch road 21a and the second step-down rectifier branch road 21b.This first step-down rectifier branch road 21a comprises the first pressure unit that is comprised of resistance R 21, R22 and the R23 of three series connection and first capacitor C 21 in parallel with resistance R 21 and R22, and the first bridge rectifier unit that is comprised of four diode D1, D2, D3 and D4.Thereby this first step-down rectifier branch road 21a is connected in series with this mu balanced circuit 22 as other each circuit stable dc power supply is provided.This second step-down rectifier branch road 21b comprises the second pressure unit that is comprised of resistance R 24, R25 and the R26 of three series connection and second capacitor C 22 in parallel with resistance R 24 and R25 equally, and the second bridge rectifier unit that is comprised of four diode D5, D6, D7 and D4.The direct supply of this second step-down rectifier branch road 21b output provides stable 24V direct supply for this relay K 1 behind one second stabilivolt ZD2.Wherein, this first bridge rectifier unit and this this diode of the second bridge rectifier units shared D4.The capacitance of this first capacitor C 21 is 0.047 μ F, and the capacitance of this second capacitor C 22 is 0.33 μ F.
This mu balanced circuit 22 comprises an integrated three-terminal regulator 222 and first stabilivolt ZD1 and a plurality of electric capacity in parallel with these integrated three-terminal regulator 222 input ends and output terminal.After carrying out the direct supply of the first step-down rectifier branch road 21a voltage stabilizing and process, this mu balanced circuit 22 provides galvanic current source Vcc for other each circuit.
This single chip machine controlling circuit 23 comprises a single-chip microcomputer 231, receive this single-chip microcomputer 231 respectively lighting time regulating circuit 24, sensitivity adjusting circuit 25, ambient brightness regulating circuit 26 and infrared signal detect and the adjusting or detection signal of amplifying circuit 28 after, then at the disconnection of sending control signal pilot relay K1 and closed and control LED indicating circuit 27.
Lighting time regulating circuit 24 specifically comprise one lighting time regulator potentiometer 242, lighting time, regulator potentiometer 242 was sent to single-chip microcomputer 231 with conditioning signal, single-chip microcomputer 231 according to this lighting time regulator potentiometer 242 adjustment information can change time of the bright light of load 30 pluggeds.
Ambient brightness regulating circuit 26 comprises a luminance potentiometer 262 and a photodiode 264 of series connection.Can regulate effective working environment brightness value by the resistance of brightness adjusting regulator potentiometer 262, respond to the external environment brightness by photodiode 264, and the ambient brightness signal is sent to single-chip microcomputer 231.
Infrared signal detects and amplifying circuit 28 comprises infrared inductor 282, and infrared inductor 282 is sent to single-chip microcomputer 231 after the signal that detects is passed through first signal amplifier 284 and secondary signal amplifier 286 and amplifying circuit amplification thereof.
With respect to prior art, the step-down rectifying circuit of infrared induction controller of the present invention comprises respectively two step-down rectifier branch roads, one of them step-down rectifier branch road provides direct supply for each functional circuit, the power that this part consumes is less than 0.2W, another step-down rectifier branch road provides direct supply for relay specially, the power of this part consumption is about 0.5W, then when relay disconnects (standby mode), for providing the step-down rectifier branch road of direct supply, this relay opens circuit simultaneously, thereby this branch road does not consume extra power, the power of whole circuitry consumes has reached the effect that reduces the infrared induction controller power consumption below 0.2W.
The present invention is not limited to above-mentioned embodiment, if various changes of the present invention or distortion are not broken away from the spirit and scope of the present invention, if these changes and distortion belong within claim of the present invention and the equivalent technologies scope, then the present invention also is intended to comprise these changes and distortion.
Claims (6)
1. a low-power-consumption infrared induction controller is characterized in that: comprise
One infrared signal detects and amplifying circuit (28), comprises an infrared inductor (282) and signal amplification circuit thereof;
One single chip machine controlling circuit (23) comprises a single-chip microcomputer (231);
One relay drive circuit (29) comprises a relay (K1); And
One step-down rectifying circuit (21), it comprises the first step-down rectifier branch road (21a) and the second step-down rectifier branch road (21b), this the first step-down rectifier branch road (21a) offers this infrared signal detection and amplifying circuit (28) and single chip machine controlling circuit (23) after alternating current is converted to direct current, this the second step-down rectifier branch road (21b) offers this relay drive circuit (29) after alternating current is converted to direct current, when this relay (K1) disconnected, this second step-down rectifier branch road (21b) was off state;
This infrared inductor (282) is sent to single-chip microcomputer (231) with the signal that detects after signal amplification circuit amplifies, single-chip microcomputer (231) sends adhesive and the disconnection of signal control relay (K1);
This first step-down rectifier branch road comprises the first pressure unit that is comprised of the resistance R 21 of three series connection, R22, R23 and first capacitor C 21 in parallel with two resistance R 21, R22, and the first bridge rectifier unit that is formed by four diode D1, D2, D3, D4, after two diode D1, D2 serial connections in this first bridge rectifier unit, diode D3, the D4 that is connected in series with two other again is in parallel, and this first pressure unit is connected between two diode D1, the D2 wherein being connected in series of this first bridge rectifier unit; This second step-down rectifier branch road comprises the second pressure unit that is comprised of the resistance R 24 of three series connection, R25, R26 and second capacitor C 22 in parallel with two resistance R 24, R25, and the second bridge rectifier unit that is formed by four diode D5, D6, D7, D4, after two diode D5, D7 serial connections of this second bridge rectifier unit, diode D6, the D4 that is connected in series with two other again is in parallel, and this second pressure unit is connected between two diode D5, the D7 wherein being connected in series of this second bridge rectifier unit; Wherein, this first bridge rectifier unit and this second bridge rectifier units shared one diode D4;
Further, also comprise a mu balanced circuit (22), it is comprised of an integrated three-terminal regulator (222) and the first stabilivolt (ZD1) and a plurality of electric capacity in parallel with this integrated three-terminal regulator input end and output terminal, and this mu balanced circuit (22) carries out offering after voltage stabilizing is processed this infrared signal detection and amplifying circuit (28) and single chip machine controlling circuit (23) with the direct supply of the first step-down rectifier branch road (21a).
2. infrared induction controller as claimed in claim 1, it is characterized in that: the capacitance of this first electric capacity (C21) is 0.047 μ F, the capacitance of this second electric capacity (C22) is 0.33 μ F.
3. infrared induction controller as claimed in claim 1, it is characterized in that: also comprise the ambient brightness regulating circuit (26) that is formed by a luminance potentiometer (262) of connecting and a photodiode (264), the brightness of photodiode (264) induction external environment, and the ambient brightness signal is sent to single-chip microcomputer (231), and can regulate working environment brightness by the resistance of brightness adjusting regulator potentiometer (262).
4. infrared induction controller as claimed in claim 1 is characterized in that: also comprise a lighting time regulating circuit (24) that is connected with single-chip microcomputer (231).
5. infrared induction controller as claimed in claim 1, it is characterized in that: also comprise the LED indicating circuit (27) that is comprised of a resistance and a light emitting diode (272), single-chip microcomputer (231) is controlled this light emitting diode (272) bright light or is turned off the light to indicate the duty of single-chip microcomputer (231).
6. infrared induction controller as claimed in claim 1, it is characterized in that: also comprise the sensitivity adjusting circuit (25) that is comprised of Adjustment of sensitivity potentiometer (252), single-chip microcomputer (231) is according to the sensitivity of electric potential signal control infrared inductor (282) sensing of Adjustment of sensitivity potentiometer (252).
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CN 201110020212 CN102176800B (en) | 2011-01-18 | 2011-01-18 | Low-power consumption infrared sensing controller |
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CN 201110020212 CN102176800B (en) | 2011-01-18 | 2011-01-18 | Low-power consumption infrared sensing controller |
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CN102176800B true CN102176800B (en) | 2013-10-23 |
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Families Citing this family (3)
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CN107148120A (en) * | 2017-06-30 | 2017-09-08 | 台州市椒光照明有限公司 | A kind of induction type Width funtion LED lamp drive circuit |
CN107317302A (en) * | 2017-08-08 | 2017-11-03 | 成都其联科技有限公司 | It is a kind of to be applied to golden guard system and take circuit with the gold for automatically powering off management function |
CN107370113A (en) * | 2017-08-08 | 2017-11-21 | 成都其联科技有限公司 | Designed based on infrared electronic technology and there is the golden guard system of power-off protection function |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN201298836Y (en) * | 2008-11-21 | 2009-08-26 | 傅景灿 | Pyroelectricity infrared induction switch |
CN201571239U (en) * | 2009-12-30 | 2010-09-01 | 昆明理工大学 | Infrared automatic switch |
CN201965457U (en) * | 2011-01-18 | 2011-09-07 | 广州市番禺奥莱照明电器有限公司 | Low power consumption infrared-sensing controller |
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Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201298836Y (en) * | 2008-11-21 | 2009-08-26 | 傅景灿 | Pyroelectricity infrared induction switch |
CN201571239U (en) * | 2009-12-30 | 2010-09-01 | 昆明理工大学 | Infrared automatic switch |
CN201965457U (en) * | 2011-01-18 | 2011-09-07 | 广州市番禺奥莱照明电器有限公司 | Low power consumption infrared-sensing controller |
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