CN201682471U - Time delay switch of single live wire controllable energy-saving lamp load - Google Patents

Time delay switch of single live wire controllable energy-saving lamp load Download PDF

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Publication number
CN201682471U
CN201682471U CN2010201327785U CN201020132778U CN201682471U CN 201682471 U CN201682471 U CN 201682471U CN 2010201327785 U CN2010201327785 U CN 2010201327785U CN 201020132778 U CN201020132778 U CN 201020132778U CN 201682471 U CN201682471 U CN 201682471U
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resistance
capacitor
infrared sensor
signal processor
sensor signal
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Expired - Lifetime
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CN2010201327785U
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陈玉
张兴芳
石勇
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Zhejiang Chint Building Electrics Co Ltd
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Zhejiang Chint Building Electrics Co Ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B20/00Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps

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Abstract

The utility model discloses a time delay switch of a single live wire controllable energy-saving lamp load, which comprises a power supply, a rectification circuit, a silicon controlled circuit, a silicon controlled trigger delay circuit, a constant current source circuit and a sensor working circuit, and is characterized in that the sensor working circuit is one type of the touch, optical and human body infrared signal sensor working circuits, an infrared sensing signal processor U2 in the silicon controlled trigger delay circuit adopts BISS0001 or RT1072JY. The utility model meets the requirement of no flashing of the energy saving lamp in a static state, adopts single live wire control, so not only filament lamps can be controlled, but also the energy-saving lamp and fluorescent lamps can be controlled, and thereby the utility model can be applied on most resistive, inductive, capacitive and other loads. In addition, the utility model has high sensitivity, can be provided with various sensor signals, and has very low power consumption.

Description

The delay switch of a kind of single live wire may command electricity-saving lamp load
Technical field
The utility model relates to the delay switch field, relates in particular to single live wire delay switch, the delay switch of specifically a kind of single live wire may command electricity-saving lamp load.
Background technology
Along with development of electronic technology, various electronic time-delay switchs have obtained using widely, and people use more convenient, and are more energy-saving and cost-reducing.But the delay switch major part of using can only be controlled resistive load at present, as incandescent lamp.And in single live wire technology, control electricity-saving lamp, fluorescent lamp and so on load, under turn-off, load meeting flicker does not stop, and this is because electricity-saving lamp and fluorescent lamp load starting resistor are very low, flow through the starting resistor that has reached load after the current charges of circuit, and the scintillation that causes.Even the delay switch of indivedual producers also can be with the electricity-saving lamp of a part, but still can not satisfy the electricity-saving lamp type of various complexity like this now generally.
Therefore need the most of electricity-saving lamp of a kind of energy control, and after turning off the light, single live wire delay switch that can not glimmer.
Summary of the invention
To be solved in the utility model is the problems referred to above that present technology exists, and aims to provide the single live wire connection of a kind of employing, has low-power consumption, can repeat to trigger again, delay switch reliable delay working and the load of may command electricity-saving lamp.
The technical scheme that addresses the above problem employing is: the delay switch of a kind of single live wire may command electricity-saving lamp load, comprise power supply, rectification circuit, ghyristor circuit, controllable silicon triggers delay circuit, constant-current source circuit and working sensor circuit, it is characterized in that described working sensor circuit is for touching, the working sensor circuit of any type in acousto-optic or the human infrared signal, the infrared sensor signal processor U2 that described controllable silicon triggers in the delay circuit adopts BISS0001 or RT1072JY, and described constant-current source circuit is at delay switch and is constant current output under the static operating mode.
The delay switch of single live wire may command electricity-saving lamp of the present utility model load, external touch, acousto-optic or human infrared signal are through the working sensor circuit, and after BISS0001 or RT1072JY preliminary treatment, the SCR control utmost point is controlled in output.When delay switch was in static operating mode, load was not worked, described constant-current source circuit, and no matter how how load changes, and its electric current is held constant at a numerical value that is lower than starting current, has satisfied the requirement that electricity-saving lamp does not glimmer when static.
As seen, the delay switch of single live wire may command electricity-saving lamp of the present utility model load, single fire control system, may command incandescent lamp not only, and can control electricity-saving lamp and fluorescent lamp, thereby, capacitive even load resistive, perceptual applicable to major part.And the utility model sensitivity height can be with the multiple sensors signal, and power consumption is extremely low.
According to the utility model, described ghyristor circuit comprises controllable silicon VT2, controllable silicon VT1, resistance R 13 and voltage-stabiliser tube Z3, the 2nd pin outputs level signals control ghyristor circuit of described infrared sensor signal processor U2.
According to the utility model, described constant-current source circuit comprises triode Q1, triode Q2, voltage-stabiliser tube Z1, voltage-stabiliser tube Z2, resistance R 1, resistance R 2, resistance R 3, resistance R 11, resistance R 12, diode D1, diode D2, capacitor C 1 and three terminal regulator U1.
According to the utility model, described working sensor circuit comprises sensor signal processing circuit and the output delay circuit that infrared sensor signal processor U2 and peripheral circuit thereof are formed.
Description of drawings
The utility model is described in further detail below in conjunction with accompanying drawing.
Fig. 1 is the power panel circuit diagram of the utility model delay switch, does not wherein comprise the working sensor circuit.
Fig. 2 is the circuit diagram of acousto-optic control working sensor circuit.
Fig. 3 is the circuit diagram of tactile sensor operating circuit.
Fig. 4 is the circuit diagram of human body infrared induction working sensor circuit.
Embodiment
With reference to Fig. 1, the delay switch of single live wire may command electricity-saving lamp of the present utility model load comprises that power supply, rectification circuit, ghyristor circuit, controllable silicon trigger delay circuit, constant-current source circuit, working sensor circuit (not shown).Controllable silicon triggers delay circuit and adopts infrared sensor signal processor RT1072JY, when external touch, sound or human infrared signal after transducer acts on control circuit, after the RT1072JY preliminary treatment, the output control SCR control utmost point.
Described ghyristor circuit comprises controllable silicon VT2, controllable silicon VT1, resistance R 13 and voltage-stabiliser tube Z3, the 2nd pin outputs level signals control ghyristor circuit of described infrared sensor signal processor U2.
Described constant-current source circuit comprises triode Q1, triode Q2, voltage-stabiliser tube Z1, voltage-stabiliser tube Z2, resistance R 1, resistance R 2, resistance R 3, resistance R 11, resistance R 12, diode D1, diode D2, capacitor C 1 and three terminal regulator U1.
Described working sensor circuit comprises sensor signal processing circuit and the output delay circuit that infrared sensor signal processor U2 and peripheral circuit thereof are formed, and arranges pin JT1 and JT2 and working sensor circuit by two and peg graft.
Described working sensor circuit can be any type in acousto-optic control, touch or the human body infrared induction.
With reference to Fig. 2, described working sensor circuit is a sound-light type, comprise resistance R 21, resistance R 22, resistance R 23, resistance R 24, resistance R 25, capacitor C 21, capacitor C 22, capacitor C 23, capacitor C 24, capacitor C 25, buzzer BZ1 and photo resistance RG1, the end of one terminating resistor R22 of resistance R 21, the IN2-end of infrared sensor signal processor U2 and an end of capacitor C 21, one end of another termination capacitor C 22 of resistance R 21, the end of the other end connecting resistance R25 of capacitor C 22, one end of capacitor C 23 and the OUT1 of infrared sensor signal processor U2 end, the other end of another termination capacitor C 23 of resistance R 25, one end of another termination capacitor C 25 of one end of resistance R 26 and the IN1-of infrared sensor signal processor U2 end resistance R 26, the end of another termination photo resistance RG1 of capacitor C 25, the end of buzzer BZ1, the end of resistance F27, one end of capacitor C 24 and the GND of infrared sensor signal processor U2 end, the VC end of another termination infrared sensor signal processor U2 of photo resistance RG1, the other end of the other end connecting resistance R27 of buzzer BZ1, one end of resistance R 23 and the IN1+ of infrared sensor signal processor U2 end, the end of another termination R24 of resistance R 23 and the other end of capacitor C 24, another termination infrared sensor signal processor U2 of resistance R 24+the 3V end, the other end of resistance R 22 and another termination capacitor C 21 and the OUT2 of infrared sensor signal processor U2 end, the LP+ end of infrared sensor signal processor U2 links to each other with the LP-end.
With reference to Fig. 3, described working sensor circuit is a touch-type, comprise resistance R 21, resistance R 22, resistance R 23, resistance R 24, resistance R 25, resistance R 26, resistance R 27, resistance R 28, capacitor C 21, capacitor C 22, capacitor C 23, capacitor C 24, capacitor C 25, capacitor C 26, diode D5, diode D6, conductive contact blade CM and neon bulb LP1, resistance R 27 and resistance R 28 series connection backs one termination conductive contact blade CM, the negative electrode of another terminating diode D6, the anode of diode D5, one end of resistance R 23, one end of capacitor C 24, one end of resistance R 26 and the IN1+ of infrared sensor signal processor U2 end, the end of one terminating resistor R22 of resistance R 21, one end of capacitor C 21 and the IN2-of infrared sensor signal processor U2 end, one end of another termination capacitor C 22 of electric capacity R21, the end of the other end connecting resistance R24 of capacitor C 22, one end of capacitor C 23, one end of resistance R 25 and the OUT1 of infrared sensor signal processor U2 end, the other end of another termination capacitor C 23 of resistance R 24 and the IN1-of infrared sensor signal processor U2 end, one end of another termination capacitor C 25 of resistance R 25, the other end of another termination capacitor C 24 of capacitor C 25, the other end of resistance R 26, the anode of diode D6, one end of capacitor C 26 and the GND of infrared sensor signal processor U2 end, another termination infrared sensor signal processor U2 of capacitor C 26 OUT2 end, the other end of another termination capacitor C 21 of resistance R 22 and the OUT2 of infrared sensor signal processor U2 end, the negative electrode of another terminating diode D5 of resistance R 23 and the power positive end of infrared sensor signal processor U2, neon bulb LP1 two ends connect LP+ end and the LP-end of infrared sensor signal processor U2 respectively.
With reference to Fig. 4, described working sensor circuit is the human infrared signal induction type, comprise resistance R 21, resistance R 22, resistance R 24, resistance R 25, resistance R 26, resistance R 27, photo resistance RG1, capacitor C 21, capacitor C 22, capacitor C 23, capacitor C 24, capacitor C 25 and electric infrared sensor DSG, the power positive end of the 1 termination infrared sensor signal processor U2 of electricity infrared sensor DSG, the end of the 2 terminating resistor R26 of electricity infrared sensor DSG, one end of capacitor C 24 and the IN1+ of infrared sensor signal processor U2 end, the end of the 3 termination photo resistance RG1 of electricity infrared sensor DSG, the other end of resistance R 26, the other end of capacitor C 24, one end of capacitor C 25 and the GND of infrared sensor signal processor U2 end, the end of the other end connecting resistance R27 of photo resistance RG1, the VC end of another termination infrared sensor signal processor U2 of resistance R 27, the end of the other end connecting resistance R25 of capacitor C 25, one end of another termination capacitor C 23 of resistance R 25, one end of resistance R 24 and the IN1+ of infrared sensor signal processor U2 end, the other end of the other end connecting resistance R24 of capacitor C 23, the OUT1 end of the negative terminal of capacitor C 22 and infrared sensor signal processor U2, the end of the positive terminating resistor R21 of capacitor C 22, the end of the other end connecting resistance R22 of resistance R 21, the IN2-end of one end of capacitor C 21 and the infrared sensor signal processor U2 of infrared sensor signal processor U2, the other end of another termination capacitor C 21 of electric capacity R22 and the OUT2 of infrared sensor signal processor U2 end, the LP+ end of infrared sensor signal processor U2 links to each other with the LP-end.
The operation principle of the utility model delay switch is as follows:
One, is under the quiescent conditions when delay switch, load is not worked, power supply is through after the full-wave rectification, by triode Q1, Q2, voltage-stabiliser tube Z1, Z2 and three terminal regulator U1, how also have resistance R 1, R2, R3, R11, R12 to form a no matter how load certain constant-current source circuit of variable-current, its operating current is about 30uA.And most of electricity-saving lamp load starting current is greater than 50uA, thereby satisfies the requirement that electricity-saving lamp does not glimmer when static.
Two, when transducer receives outer signals: (three kinds sensor signal frequency and signal amplitude all different)
(1) touches delay switch through resistance R 27, R28 reaches infrared sensor signal processor U2RT1072JY IN1+ end to signal, behind the amplifying circuit through chip internal and external devices composition, go to control controllable silicon VT2MCR100-8 conducting by high level of VO end output, control controllable silicon VT2CP12C60 conducting, at this moment neon bulb extinguishes, load is lighted, and load is lighted the time by resistance R 21, resistance R 22, resistance R 23, resistance R 24, resistance R 25, resistance R 26, resistance R 27, resistance R 28, capacitor C 21, capacitor C 22, capacitor C 23, capacitor C 24, the decision of outer meeting resistance electric capacity such as capacitor C 25 and capacitor C 26.
(2) after sound and light controlled delay switch receives the external sound signal, as fruit product under environment greater than 6 LUX, photo resistance RG1 is low resistive state, infrared sensor signal processor U2RT1072JY forbids triggering, when product is in environment less than 6 LUX, then photo resistance RG1 is high-impedance state, infrared sensor signal processor U2RT1072JY allows to trigger, after sensor signal process ratio and frequency-selecting are amplified, VO end output high level signal, and the high level signal delay time is by resistance R 21, resistance R 22, resistance R 23, resistance R 24, resistance R 25, capacitor C 21, capacitor C 22, capacitor C 23, the decision of outer meeting resistance electric capacity such as capacitor C 24 and capacitor C 25.
(3) after the infrared delay switch of human body receives the human mobile signal, as fruit product under environment greater than 6 LUX, photo resistance RG1 is low resistive state, infrared sensor signal processor U2RT1072JY forbids triggering, when product is in environment less than 6 LUX, then photo resistance RG1 is high-impedance state, infrared sensor signal processor U2BISS0001 allows to trigger, after sensor signal process ratio and frequency-selecting are amplified, VO end output high level signal, and the high level signal delay time is by resistance R 21, resistance R 22, resistance R 24, resistance R 25, resistance R 26, resistance R 27, capacitor C 21, capacitor C 22, capacitor C 23, the decision of outer meeting resistance electric capacity such as capacitor C 24 and capacitor C 25.
Three, when VO output high level signal, controllable silicon VT2 conducting when exchanging input 0~7.5V, is charged to capacitor C 1 rapidly through diode D2; After AC signal is greater than 7.5V, controllable silicon VT1 conducting, load is lighted.This moment, input voltage was about 1V, and capacitor C 1 stops charging, owing to be bridge rectifier, per half AC power cycle is that capacitor C 1 is charged once, and is filled to about 7.5V, can keep the above direct-current power supply complete machine of capacitor C 1 two ends output 3V/1mA and use.
What should be understood that is: the foregoing description is just to explanation of the present utility model, rather than to restriction of the present utility model, any innovation and creation that do not exceed in the utility model connotation scope all fall within the protection range of the present utility model.

Claims (8)

1. the delay switch of single live wire may command electricity-saving lamp load, comprise that power supply, rectification circuit, ghyristor circuit, controllable silicon trigger delay circuit, constant-current source circuit and working sensor circuit, it is characterized in that described working sensor circuit is the working sensor circuit of any type in touch, acousto-optic or the human infrared signal, the infrared sensor signal processor U2 that described controllable silicon triggers in the delay circuit adopts BISS0001 or RT1072JY, and described constant-current source circuit is at delay switch and is constant current output under the static operating mode.
2. the delay switch of single live wire may command electricity-saving lamp as claimed in claim 1 load, it is characterized in that ghyristor circuit comprises controllable silicon VT2, controllable silicon VT1, resistance R 13 and voltage-stabiliser tube Z3, the 2nd pin outputs level signals control ghyristor circuit of described infrared sensor signal processor U2.
3. the delay switch of single live wire may command electricity-saving lamp as claimed in claim 1 load is characterized in that described constant-current source circuit comprises triode Q1, triode Q2, voltage-stabiliser tube Z1, voltage-stabiliser tube Z2, resistance R 1, resistance R 2, resistance R 3, resistance R 11, resistance R 12, diode D2, diode D3, capacitor C 1 and three terminal regulator U1.
4. the delay switch of single live wire may command electricity-saving lamp as claimed in claim 1 load is characterized in that sensor signal processing circuit and output delay circuit that described working sensor circuit comprises that infrared sensor signal processor U2 and peripheral circuit thereof are formed.
5. as the delay switch of any one described single live wire may command electricity-saving lamp load of claim 1-4, it is characterized in that described working sensor circuit is a sound-light type, comprise resistance R 21, resistance R 22, resistance R 23, resistance R 24, resistance R 25, capacitor C 21, capacitor C 22, capacitor C 23, capacitor C 24, capacitor C 25, as acoustic sensor piezo buzzer BZ1 and photo resistance RG1, the end of one terminating resistor R22 of resistance R 21, the IN2-end of infrared sensor signal processor U2 and an end of capacitor C 21, one end of another termination capacitor C 22 of resistance R 21, the end of the other end connecting resistance R25 of capacitor C 22, one end of capacitor C 23 and the OUT1 of infrared sensor signal processor U2 end, the other end of another termination capacitor C 23 of resistance R 25, one end of another termination capacitor C 25 of one end of resistance R 26 and the IN1 of infrared sensor signal processor U2 one end resistance R 26, the end of another termination photo resistance RG1 of capacitor C 25, the end of buzzer BZ1, one end of resistance R 27, one end of capacitor C 24 and the GND of infrared sensor signal processor U2 end, the VC end of another termination infrared sensor signal processor U2 of photo resistance RG1, the other end of the other end connecting resistance R27 of buzzer BZ1, one end of resistance R 23 and the IN1+ of infrared sensor signal processor U2 end, the end of another termination R24 of resistance R 23 and the other end of capacitor C 24, another termination infrared sensor signal processor U2 of resistance R 24+the 3V end, the other end of resistance R 22 and another termination capacitor C 21 and the OUT2 of infrared sensor signal processor U2 end, the LP+ end links to each other with the LP-end.
6. as the delay switch of any one described single live wire may command electricity-saving lamp load of claim 1-4, it is characterized in that described working sensor circuit is a touch-type, comprise resistance R 21, resistance R 22, resistance R 23, resistance R 24, resistance R 25, resistance R 26, resistance R 27, resistance R 28, capacitor C 21, capacitor C 22, capacitor C 23, capacitor C 24, capacitor C 25, capacitor C 26, diode D5, diode D6, conductive contact blade CM and neon bulb LP1, resistance R 27 and resistance R 28 series connection backs one termination conductive contact blade CM, the negative electrode of another terminating diode D6, the anode of diode D5, one end of resistance R 23, one end of capacitor C 24, one end of resistance R 26 and the IN1+ of infrared sensor signal processor U2 end, the end of one terminating resistor R22 of resistance R 21, IN2 one end of one end of capacitor C 21 and infrared sensor signal processor U2, one end of another termination capacitor C 22 of electric capacity R21, the end of the other end connecting resistance R24 of capacitor C 22, one end of capacitor C 23, one end of resistance R 25 and the OUT1 of infrared sensor signal processor U2 end, IN1 one end of the other end of another termination capacitor C 23 of resistance R 24 and infrared sensor signal processor U2, one end of another termination capacitor C 25 of resistance R 25, the other end of another termination capacitor C 24 of capacitor C 25, the other end of resistance R 26, the anode of diode D6, one end of capacitor C 26 and the GND of infrared sensor signal processor U2 end, another termination infrared sensor signal processor U2 of capacitor C 26 OUT2 end, the other end of another termination capacitor C 21 of resistance R 22 and the OUT2 of infrared sensor signal processor U2 end, the negative electrode of another terminating diode D5 of resistance R 23 and the power positive end of infrared sensor signal processor U2, neon bulb LP1 two ends connect LP+ end and LP-end respectively.
7. as the delay switch of any one described single live wire may command electricity-saving lamp load of claim 1-4, it is characterized in that described working sensor circuit is the human infrared signal induction type, comprise resistance R 21, resistance R 22, resistance R 24, resistance R 25, resistance R 26, resistance R 27, photo resistance RG1, capacitor C 21, capacitor C 22, capacitor C 23, capacitor C 24, capacitor C 25 and electric infrared sensor DSG, the power positive end of the D termination infrared sensor signal processor U2 of infrared sensor DSG, the end of the S terminating resistor R26 of electricity infrared sensor DSG, one end of capacitor C 24 and the IN1+ of infrared sensor signal processor U2 end, the end of the G termination photo resistance RG1 of infrared sensor DSG, the other end of resistance R 26, the other end of capacitor C 24, one end of capacitor C 25 and the GND of infrared sensor signal processor U2 end, the end of the other end connecting resistance R27 of photo resistance RG1, the VC end of another termination infrared sensor signal processor U2 of resistance R 27, the end of the other end connecting resistance R25 of capacitor C 25, one end of another termination capacitor C 23 of resistance R 25, IN1 one end of one end of resistance R 24 and infrared sensor signal processor U2, the other end of the other end connecting resistance R24 of capacitor C 23, the OUT1 end of the negative terminal of capacitor C 22 and infrared sensor signal processor U2, the end of the positive terminating resistor R21 of capacitor C 22, the end of the other end connecting resistance R22 of resistance R 21, IN2 one end of one end of capacitor C 21 and infrared sensor signal processor U2, the other end of another termination capacitor C 21 of electric capacity R22 and the OUT2 of infrared sensor signal processor U2 end, the LP+ end links to each other with LP one end.
8. as the delay switch of any one described single live wire may command electricity-saving lamp load of claim 1-4, it is characterized in that described controllable silicon triggers delay circuit and the working sensor circuit adopts row's cushion to connect.
CN2010201327785U 2010-03-17 2010-03-17 Time delay switch of single live wire controllable energy-saving lamp load Expired - Lifetime CN201682471U (en)

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Application Number Priority Date Filing Date Title
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109217442A (en) * 2018-10-09 2019-01-15 瑞纳智能设备股份有限公司 A kind of power supply unit and method based on single live wire power getting module

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109217442A (en) * 2018-10-09 2019-01-15 瑞纳智能设备股份有限公司 A kind of power supply unit and method based on single live wire power getting module
CN109217442B (en) * 2018-10-09 2021-11-02 瑞纳智能设备股份有限公司 Power supply device and method based on single-live-wire power taking module

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Granted publication date: 20101222