CN205196011U - Corridor entrance guard lamp control system - Google Patents
Corridor entrance guard lamp control system Download PDFInfo
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- CN205196011U CN205196011U CN201521045286.1U CN201521045286U CN205196011U CN 205196011 U CN205196011 U CN 205196011U CN 201521045286 U CN201521045286 U CN 201521045286U CN 205196011 U CN205196011 U CN 205196011U
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B20/00—Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps
- Y02B20/30—Semiconductor lamps, e.g. solid state lamps [SSL] light emitting diodes [LED] or organic LED [OLED]
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Abstract
The utility model discloses a corridor entrance guard lamp control system is become with the corridor banks by ambient brightness sensor, human body detection module, access control system, singlechip, a drive module, time delay change optical module, entrance guard's lamp, the 2nd drive module, output, access control system and the human body detection module's of ambient brightness sensor output parallel connection microcontroller type pin, a singlechip output pin parallel connection drive module input and the 2nd drive module input, a drive module output are connected the time delay and are become the optical module input, and the time delay becomes the optical module output and connects entrance guard's lamp input, and corridor lamp input is connected to the 2nd drive module output. The utility model discloses utilizing the singlechip to realize the switching of entrance guard's lamp and corridor lamp, making things convenient for the resident family to open access control system evening, practice thrift the electric energy, having set up the time delay simultaneously and having become the optical module, entrance guard's lamp is gradually bright when having the resident family to be close to, access control system turn on back entrance guard's lamp gradually dark while corridor lamp light, make things convenient for the resident family to adapt to bright environment.
Description
Technical field
The utility model relates to a kind of corridor lamp Ore-controlling Role, particularly relates to a kind of corridor gate inhibition lighting control system, belongs to corridor lighting field.
Background technology
Increasing community set up gate control system at corridor mouth place now, has the gate control systems such as cipher, finger-print type, card-scanning type, prevents entering of non-resident personnel, ensures the safety of community.But time at night, resident family also needs to find badge, key or searching password input keyboard etc. by feeling about in the dark and opens gate control system before entering corridor, also need afterwards to enter in corridor and open corridor lamp, very inconvenient.And have the gate control system of backlight panel, conveniently resident family's enabling can light by retentive control panel all the time at night, waste electric energy, is unfavorable for energy-conservation.
Summary of the invention
The purpose of this utility model is to provide a kind of corridor gate inhibition lighting control system, solves the technical problem that electric energy was opened, wasted in current corridor mouth gate inhibition inconvenience in evening.
The purpose of this utility model is achieved by the following technical programs: a kind of corridor gate inhibition lighting control system, is become optical module 6, gate inhibition's lamp 7, second driver module 8 and corridor lamp 9 formed by ambient light sensor 1, human detection module 2, gate control system 3, single-chip microcomputer 4, first driver module 5, time delay; The output parallel join of the output of ambient light sensor 1, gate control system 3 and human detection module 2 is to the input pin of single-chip microcomputer 4, output pin parallel join first driver module 5 input of single-chip microcomputer 4 and the second driver module 8 input, first driver module 5 output connects time delay and becomes optical module 6 input, time delay becomes optical module 6 output and connects gate inhibition's lamp 7 input, and the second driver module 8 output connects corridor lamp 9 input.
The purpose of this utility model can also be realized further by following technical measures: described first driver module 5 comprises the first optocoupler U1, the first resistance R1, the second resistance R2, the first triode VT1, the first diode VD1 and the first relay K 1, described first optocoupler U1 comprises the first LED 1 and the first phototriode BG1, and described first relay K 1 comprises the first coil RC1 and the first contact R L1; + 5V power supply connects first resistance R1 one end of the first optocoupler U1, and the first resistance R1 other end connects the positive pole of first LED 1 of the first optocoupler U1, and the negative pole of the first LED 1 connects incoming level signal; First LED 1 and the first phototriode BG1 are encapsulated in the first optocoupler U1; The collector electrode of the first phototriode BG1 in the first optocoupler U1 connects one end of the second resistance R2, another termination driving power VCC1 of the second resistance R2, the emitter of the first phototriode BG1 in the first optocoupler U1 is connected with the base stage of the first triode VT1, the first triode VT1 grounded emitter; The collector electrode of the first triode VT1 connects first coil RC1 one end of the first relay K 1, another termination driving power of the first coil RC1 VCC1 of the first relay K 1; Current Control first contact R L1 in first coil RC1 of the first relay K 1 disconnects; The two ends access delay of the first contact R L1 becomes optical module 6; First fly-wheel diode VD1 is connected in parallel on the first coil RC1 two ends of the first relay K 1, and negative pole connects power supply, and positive pole connects the first triode VT1 collector electrode.
Described time delay becomes optical module 6 and comprises the 3rd resistance R3, the 4th resistance R4, the 5th resistance R5, electric capacity C, the second triode VT2, the 3rd triode VT3 and bridge rectifier UR; The cathode power supply output of the first contact R L1 mono-termination bridge rectifier UR of the first relay K 1 of the first driver module 5, the other end connects one end of the 3rd resistance R3, the other end of the 3rd resistance R3 connects one end of the 4th resistance R4, access the positive pole of electric capacity C simultaneously, the other end of the 4th resistance connects the base stage of the second triode VT2, the collector electrode of the second triode VT2 connects one end of the 5th resistance R5, and the other end of the 5th resistance R5 connects the cathode power supply output of bridge rectifier UR; The emitter of the second triode connects the base stage of the 3rd triode VT3, and the collector electrode of the 3rd triode VT3 connects the negative terminal of gate inhibition's lamp 7, and the positive pole of gate inhibition's lamp 7 connects the cathode power supply output of bridge rectifier UR; The emitter of the 3rd triode VT3 and the negative pole of electric capacity C access the negative power supply output of rectification circuit UR simultaneously; The two ends of two ac input end access 220V AC power of bridge rectifier UR.
Described second driver module 8 comprises the second optocoupler U2, the 6th resistance R6, the 7th resistance R7, the 4th triode VT4, the second diode VD2 and the second relay K 2, described second optocoupler U2 comprises the second LED 2 and the second phototriode BG2, and described second relay K 2 comprises the second coil RC2 and the second contact R L2; + 5V power supply connects the 6th resistance R6 one end of the second optocoupler U2, and the 6th resistance R6 other end connects the positive pole of second LED 2 of the second optocoupler U2, and the negative pole of the second LED 2 connects incoming level signal; Second LED 2 and the second phototriode BG2 are encapsulated in the second optocoupler U2; The collector electrode of the second phototriode BG2 in the second optocoupler U2 connects one end of the 7th resistance R7, another termination driving power VCC2 of the 7th resistance R7, the emitter of the second phototriode BG2 in the second optocoupler U2 is connected with the base stage of the 4th triode VT4, the 4th triode VT4 grounded emitter; The collector electrode of the 4th triode VT4 connects second coil RC2 one end of the second relay K 2, another termination driving power of the second coil RC2 VCC2 of the second relay K 2; Current Control second contact R L2 in second coil RC2 of the second relay K 2 disconnects; One end access corridor lamp 9 of the second contact R L2, other end ground connection; Second fly-wheel diode VD2 is connected in parallel on the second coil RC2 two ends of the second relay K 2, and negative pole connects power supply, and positive pole connects the second triode VT2 collector electrode.
Aforementioned corridor gate inhibition lighting control system, wherein said gate control system 3 can be the gate control system of arbitrary kind.
Aforementioned corridor gate inhibition lighting control system, the bridge rectifier UR that wherein said time delay becomes optical module 6 is made up of four diodes.
Compared with prior art, the beneficial effects of the utility model are: the switching utilizing chip microcontroller gate inhibition lamp and corridor lamp, facilitate resident family to open gate control system evening, do not need manual unlocking corridor lamp, saved electric energy simultaneously.In addition, corridor gate inhibition lighting control system is also provided with time delay and becomes optical module, have resident family near time gate inhibition lamp gradually bright, gate control system turn on rear gate inhibition's lamp gradually dark corridor lamp simultaneously light, facilitate the eyes of resident family to adapt to bright environment.
Accompanying drawing explanation
Fig. 1 is the utility model corridor gate inhibition lighting control system structure chart;
Fig. 2 is that the utility model corridor gate inhibition lighting control system first driver module and time delay become optical module circuit diagram;
Fig. 3 is the utility model corridor gate inhibition lighting control system second driver module circuit diagram.
Embodiment
Below in conjunction with the drawings and specific embodiments, the utility model is described in further detail.In FIG, corridor gate inhibition lighting control system of the present utility model, is become optical module 6, gate inhibition's lamp 7, second driver module 8 and corridor lamp 9 formed by ambient light sensor 1, human detection module 2, gate control system 3, single-chip microcomputer 4, first driver module 5, time delay; The output parallel join of the output of ambient light sensor 1, gate control system 3 and human detection module 2 is to the input pin of single-chip microcomputer 4, output pin parallel join first driver module 5 input of single-chip microcomputer 4 and the second driver module 8 input, first driver module 5 output connects time delay and becomes optical module 6 input, time delay becomes optical module 6 output and connects gate inhibition's lamp 7 input, and the second driver module 8 output connects corridor lamp 9 input.
In fig. 2, described first driver module 5 comprises the first optocoupler U1, the first resistance R1, the second resistance R2, the first triode VT1, the first diode VD1 and the first relay K 1, described first optocoupler U1 comprises the first LED 1 and the first phototriode BG1, and described first relay K 1 comprises the first coil RC1 and the first contact R L1; + 5V power supply connects first resistance R1 one end of the first optocoupler U1, and the first resistance R1 other end connects the positive pole of first LED 1 of the first optocoupler U1, and the negative pole of the first LED 1 connects incoming level signal; First LED 1 and the first phototriode BG1 are encapsulated in the first optocoupler U1; The collector electrode of the first phototriode BG1 in the first optocoupler U1 connects one end of the second resistance R2, another termination driving power VCC1 of the second resistance R2, the emitter of the first phototriode BG1 in the first optocoupler U1 is connected with the base stage of the first triode VT1, the first triode VT1 grounded emitter; The collector electrode of the first triode VT1 connects first coil RC1 one end of the first relay K 1, another termination driving power of the first coil RC1 VCC1 of the first relay K 1; Current Control first contact R L1 in first coil RC1 of the first relay K 1 disconnects.The two ends access delay of the first contact R L1 becomes optical module 6; First fly-wheel diode VD1 is connected in parallel on the first coil RC1 two ends of the first relay K 1, and negative pole connects power supply, and positive pole connects the first triode VT1 collector electrode.
Described time delay becomes optical module 6 and comprises the 3rd resistance R3, the 4th resistance R4, the 5th resistance R5, electric capacity C, the second triode VT2, the 3rd triode VT3 and bridge rectifier UR; The cathode power supply output of the first contact R L1 mono-termination bridge rectifier UR of the first relay K 1 of the first driver module 5, the other end connects one end of the 3rd resistance R3, the other end of the 3rd resistance R3 connects one end of the 4th resistance R4, access the positive pole of electric capacity C simultaneously, the other end of the 4th resistance connects the base stage of the second triode VT2, the collector electrode of the second triode VT2 connects one end of the 5th resistance R5, and the other end of the 5th resistance R5 connects the cathode power supply output of bridge rectifier UR; The emitter of the second triode connects the base stage of the 3rd triode VT3, and the collector electrode of the 3rd triode VT3 connects the negative terminal of gate inhibition's lamp 7, and the positive pole of gate inhibition's lamp 7 connects the cathode power supply output of bridge rectifier UR; The emitter of the 3rd triode VT3 and the negative pole of electric capacity C access the negative power supply output of rectification circuit UR simultaneously; The two ends of two ac input end access 220V AC power of bridge rectifier UR.
In figure 3, described second driver module 8 comprises the second optocoupler U2, the 6th resistance R6, the 7th resistance R7, the 4th triode VT4, the second diode VD2 and the second relay K 2, described second optocoupler U2 comprises the second LED 2 and the second phototriode BG2, and described second relay K 2 comprises the second coil RC2 and the second contact R L2; + 5V power supply connects the 6th resistance R6 one end of the second optocoupler U2, and the 6th resistance R6 other end connects the positive pole of second LED 2 of the second optocoupler U2, and the negative pole of the second LED 2 connects incoming level signal; Second LED 2 and the second phototriode BG2 are encapsulated in the second optocoupler U2; The collector electrode of the second phototriode BG2 in the second optocoupler U2 connects one end of the 7th resistance R7, another termination driving power VCC2 of the 7th resistance R7, the emitter of the second phototriode BG2 in the second optocoupler U2 is connected with the base stage of the 4th triode VT4, the 4th triode VT4 grounded emitter; The collector electrode of the 4th triode VT4 connects second coil RC2 one end of the second relay K 2, another termination driving power of the second coil RC2 VCC2 of the second relay K 2; Current Control second contact R L2 in second coil RC2 of the second relay K 2 disconnects; One end access corridor lamp 9 of the second contact R L2, other end ground connection; Second fly-wheel diode VD2 is connected in parallel on the second coil RC2 two ends of the second relay K 2, and negative pole connects power supply, and positive pole connects the second triode VT2 collector electrode.
Operation principle of the present utility model is as follows: at day, and ambient light sensor 1 exports high level, and single-chip microcomputer 4 does not work.First contact R L1 of the first relay K 1 and the second contact R L2 of the second relay K 2 disconnects, and the second triode VT2 and the 3rd triode VT3 is all in cut-off region, and gate inhibition's lamp 7 and corridor lamp 9 all do not work.
At dark, ambient light sensor 1 output low level, single-chip microcomputer 4 works.Under single-chip microcomputer operating state, when having people near gate control system, human detection module 2 output outputs signal single-chip microcomputer 4, single-chip microcomputer 4 exports the first optocoupler U1 that high level enters the first driver module 5, the signal conversion of electrical-optical-electricity is carried out in the first optocoupler U1, high level signal after conversion enters the base stage of the first triode VT1, first triode VT1 saturation conduction, first coil RC1 energising conducting of the first relay K 1 simultaneously, produce galvanomagnetic effect, what make the first relay K 1 often opens the first contact R L1 adhesive.
First relay K 1 often open the first contact R L1 attracting state under, 220V AC power is through bridge rectifier UR, charge to electric capacity C, electric capacity C both end voltage is made to increase gradually, thus make the second triode VT2 two ends acquisition base bias current from small to large, second triode VT1 and the 3rd triode VT3 enters amplification region by cut-off region, final conducting completely.Gate inhibition's lamp 7 from secretly brightening, is finally stabilized in the brightest state thereupon.
When gate control system 3 is opened, gate control system 3 input signal is to the input pin of single-chip microcomputer 4, single-chip microcomputer 4 connects the output output low level signal of the first driver module 5, output signal enters the signal conversion that the first optocoupler U1 carries out electrical-optical-electricity, low level signal after conversion enters the base stage of the first triode VT1, first triode VT1 is in cut-off region, and in the first coil RC1 of simultaneously the first relay K 1, no current passes through, and the first contact R L1 that often opens of the first relay K 1 disconnects.Now time delay is become the electric charge stored in the electric capacity C of optical module 6 and is discharged to the emitter of the second triode VT2 by the 4th resistance R4, and the second triode VT2 and the 3rd triode VT3 constantly enters amplification region along with electric discharge, finally becomes cut-off state.The brightness of gate inhibition's lamp 7, thereupon by bright dimmed, is finally extinguished.
Simultaneously, single-chip microcomputer 4 exports the second optocoupler U2 that high level enters the second driver module 8, the signal conversion of electrical-optical-electricity is carried out in the second optocoupler U2, high level signal after conversion enters the base stage of the 4th triode VT4,4th triode VT4 saturation conduction, second coil RC2 energising conducting of the second relay K 2 simultaneously, produce galvanomagnetic effect, what make the second relay K 2 often opens the second contact R L2 adhesive.
The bright dark transformation period of described gate inhibition's lamp 7 is determined by the parameter of the 3rd resistance R3, the 4th resistance R4 and electric capacity C respectively.
Described 3rd triode VT3 should adopt the high-power NPN triode of high back-pressure.
In addition to the implementation, the utility model can also have other execution modes, and all employings are equal to the technical scheme of replacement or equivalent transformation formation, all drop in the protection range of the utility model requirement.
Claims (5)
1. a corridor gate inhibition lighting control system, it is characterized in that, become optical module (6), gate inhibition's lamp (7), the second driver module (8) and corridor lamp (9) formed by ambient light sensor (1), human detection module (2), gate control system (3), single-chip microcomputer (4), the first driver module (5), time delay; The output parallel join of the output of ambient light sensor (1), gate control system (3) and human detection module (2) is to the input pin of single-chip microcomputer (4), output pin parallel join first driver module (5) input of single-chip microcomputer (4) and the second driver module (8) input, first driver module (5) output connects time delay and becomes optical module (6) input, time delay becomes optical module (6) output and connects gate inhibition's lamp (7) input, and the second driver module (8) output connects corridor lamp (9) input.
2. a kind of corridor gate inhibition lighting control system according to claim 1, it is characterized in that, described first driver module (5) comprises the first optocoupler U1, the first resistance R1, the second resistance R2, the first triode VT1, the first diode VD1 and the first relay K 1, described first optocoupler U1 comprises the first LED 1 and the first phototriode BG1, and described first relay K 1 comprises the first coil RC1 and the first contact R L1; + 5V power supply connects first resistance R1 one end of the first optocoupler U1, and the first resistance R1 other end connects the positive pole of first LED 1 of the first optocoupler U1, and the negative pole of the first LED 1 connects incoming level signal; First LED 1 and the first phototriode BG1 are encapsulated in the first optocoupler U1; The collector electrode of the first phototriode BG1 in the first optocoupler U1 connects one end of the second resistance R2, another termination driving power VCC1 of the second resistance R2, the emitter of the first phototriode BG1 in the first optocoupler U1 is connected with the base stage of the first triode VT1, the first triode VT1 grounded emitter; The collector electrode of the first triode VT1 connects first coil RC1 one end of the first relay K 1, another termination driving power of the first coil RC1 VCC1 of the first relay K 1; Current Control first contact R L1 in first coil RC1 of the first relay K 1 disconnects; The two ends access delay of the first contact R L1 becomes optical module (6); First fly-wheel diode VD1 is connected in parallel on the first coil RC1 two ends of the first relay K 1, and negative pole connects power supply, and positive pole connects the first triode VT1 collector electrode.
3. a kind of corridor gate inhibition lighting control system according to claim 1, it is characterized in that, described time delay becomes optical module (6) and comprises the 3rd resistance R3, the 4th resistance R4, the 5th resistance R5, electric capacity C, the second triode VT2, the 3rd triode VT3 and bridge rectifier UR; The cathode power supply output of the first contact R L1 mono-termination bridge rectifier UR of the first relay K 1 of the first driver module (5), the other end connects one end of the 3rd resistance R3, the other end of the 3rd resistance R3 connects one end of the 4th resistance R4, access the positive pole of electric capacity C simultaneously, the other end of the 4th resistance connects the base stage of the second triode VT2, the collector electrode of the second triode VT2 connects one end of the 5th resistance R5, and the other end of the 5th resistance R5 connects the cathode power supply output of bridge rectifier UR; The emitter of the second triode connects the base stage of the 3rd triode VT3, and the collector electrode of the 3rd triode VT3 connects the negative terminal of gate inhibition's lamp (7), and the positive pole of gate inhibition's lamp (7) connects the cathode power supply output of bridge rectifier UR; The emitter of the 3rd triode VT3 and the negative pole of electric capacity C access the negative power supply output of rectification circuit UR simultaneously; The two ends of two ac input end access 220V AC power of bridge rectifier UR.
4. a kind of corridor gate inhibition lighting control system according to claim 1, it is characterized in that, described second driver module (8) comprises the second optocoupler U2, the 6th resistance R6, the 7th resistance R7, the 4th triode VT4, the second diode VD2 and the second relay K 2, described second optocoupler U2 comprises the second LED 2 and the second phototriode BG2, and described second relay K 2 comprises the second coil RC2 and the second contact R L2; + 5V power supply connects the 6th resistance R6 one end of the second optocoupler U2, and the 6th resistance R6 other end connects the positive pole of second LED 2 of the second optocoupler U2, and the negative pole of the second LED 2 connects incoming level signal; Second LED 2 and the second phototriode BG2 are encapsulated in the second optocoupler U2; The collector electrode of the second phototriode BG2 in the second optocoupler U2 connects one end of the 7th resistance R7, another termination driving power VCC2 of the 7th resistance R7, the emitter of the second phototriode BG2 in the second optocoupler U2 is connected with the base stage of the 4th triode VT4, the 4th triode VT4 grounded emitter; The collector electrode of the 4th triode VT4 connects second coil RC2 one end of the second relay K 2, another termination driving power of the second coil RC2 VCC2 of the second relay K 2; Current Control second contact R L2 in second coil RC2 of the second relay K 2 disconnects; One end access corridor lamp (9) of second contact R L2, other end ground connection; Second fly-wheel diode VD2 is connected in parallel on the second coil RC2 two ends of the second relay K 2, and negative pole connects power supply, and positive pole connects the second triode VT2 collector electrode.
5. a kind of corridor gate inhibition lighting control system according to claim 1 or 3, is characterized in that, the bridge rectifier UR that described time delay becomes optical module (6) is made up of four diodes.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201521045286.1U CN205196011U (en) | 2015-12-16 | 2015-12-16 | Corridor entrance guard lamp control system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201521045286.1U CN205196011U (en) | 2015-12-16 | 2015-12-16 | Corridor entrance guard lamp control system |
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CN205196011U true CN205196011U (en) | 2016-04-27 |
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CN201521045286.1U Expired - Fee Related CN205196011U (en) | 2015-12-16 | 2015-12-16 | Corridor entrance guard lamp control system |
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CN (1) | CN205196011U (en) |
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2015
- 2015-12-16 CN CN201521045286.1U patent/CN205196011U/en not_active Expired - Fee Related
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Granted publication date: 20160427 Termination date: 20161216 |