CN105430806A - Multifunctional intelligent control system for LED lamp - Google Patents
Multifunctional intelligent control system for LED lamp Download PDFInfo
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- CN105430806A CN105430806A CN201510957248.1A CN201510957248A CN105430806A CN 105430806 A CN105430806 A CN 105430806A CN 201510957248 A CN201510957248 A CN 201510957248A CN 105430806 A CN105430806 A CN 105430806A
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B45/00—Circuit arrangements for operating light-emitting diodes [LED]
- H05B45/10—Controlling the intensity of the light
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Abstract
The invention discloses a multifunctional intelligent control system for an LED lamp. The multifunctional intelligent control system is characterized by mainly comprising a central processor, a photosensitive sensor, a display, an infrared probe, a power supply, an LED lamp, an infrared signal receiving circuit, a frequency-modulated beam receiving circuit, a low-voltage load dimming circuit and a start surge current-limiting circuit, wherein the display, the infrared probe, the power supply and the LED lamp all are connected with the central processor; the infrared signal receiving circuit is connected between the infrared probe and the central processor in series; the frequency-modulated beam receiving circuit is connected between the photosensitive sensor and the central processor in series; the low-voltage load dimming circuit is connected between the central processor and the LED lamp in series; and the start surge current-limiting circuit is connected between the power supply and the central processor in series. According to the intelligent control system for the LED lamp disclosed by the invention, automatic brightness adjustment is achieved by an LED table lamp; automatic shutdown can be carried out when nobody is around; electric energy is greatly saved; the effective lifetime of the LED table lamp can be fully prolonged; and the use cost is reduced.
Description
Technical field
The present invention relates to the technical field of electronic equipment, specifically refer to the multi-functional intelligent control system of a kind of LED.
Background technology
The normally fixing light of the desk lamp used in existing family, by user's hand control switch, this desk lamp cannot regulate brightness, when dark, user can feel insufficient light, can feel again that when light is stronger light is excessively bright, the deficiency of light all likely damages human eye with excessively bright.
At present, some desk lamp can by the brightness of user's manual adjustments light, and user can the desk lamp light that is applicable to of the different adjustment of environmentally brightness, but the operation required is still too much, and the brightness of user's manual adjustments is also inaccurate.And user usually can forget closedown desk lamp when leaving, and wastes electric energy greatly.
Summary of the invention
The object of the invention is to overcome the brightness that LED desk lamp of the prior art can not regulate light automatically, the defect that can not automatically close, the invention provides the multi-functional intelligent control system of a kind of LED.
The present invention is achieved through the following technical solutions: the multi-functional intelligent control system of a kind of LED, primarily of central processing unit, light-inductive device, the display be all connected with central processing unit, infrared probe, power supply and LED, be serially connected in the infrared signal receiving circuit between infrared probe and central processing unit, be serially connected in the frequency-modulated beam receiving circuit between light-inductive device and central processing unit, be serially connected in the low-voltage load light adjusting circuit between central processing unit and LED, and the startup ICLC composition be serially connected between power supply and central processing unit.
Described infrared signal receiving circuit is by process chip U, triode VT9, triode VT10, diode D11, positive pole is connected with the N pole of diode D11 after resistance R28, the polar capacitor C13 that negative pole is connected with the emitter of triode VT9 after resistance R30, positive pole is connected with the N pole of diode D11, the polar capacitor C17 that negative pole is connected with the base stage of triode VT9 after adjustable resistance R29, one end is connected with the SC pin of process chip U, the resistance R31 that the other end is connected with the collector electrode of triode VT9, negative pole is connected with the PWM pin of process chip U, the polar capacitor C14 that positive pole is connected with the adjustable end of adjustable resistance R29, P pole is connected with the P pole of diode D11 after resistance R32, the diode D12 that N pole is connected with the SW pin of process chip U, negative pole is connected with the SHF pin of process chip U, the polar capacitor C15 that positive pole is connected with the FW pin of process chip U, P pole is connected with the SEN pin of process chip U after resistance R33, the diode D13 that N pole is connected with the emitter of triode VT10, and positive pole is connected with the OUT pin of process chip U, the polar capacitor C16 that negative pole is connected with the base stage of triode VT10 after resistance R34 forms, the VIN pin of described process chip U is connected with the negative pole of polar capacitor C14, its GND pin ground connection, the grounded collector of described triode VT10, the positive pole of described polar capacitor C13 as infrared signal receiving circuit input and be connected with infrared probe, the negative pole of described polar capacitor C16 is as infrared signal receiving circuit output and be connected with central processing unit.
Described startup ICLC is by triode VT6, triode VT7, triode VT8, field effect transistor MOS, positive pole is connected with the drain electrode of field effect transistor MOS after resistance R26, the polar capacitor C11 that negative pole is connected with the base stage of triode VT6, positive pole is connected with the positive pole of polar capacitor C11 after resistance R21 through thermistor R18 in turn, the polar capacitor C9 that negative pole is connected with the base stage of triode VT8 after resistance R19, positive pole is connected with the tie point of resistance R21 with thermistor R18 after resistance R20, the polar capacitor C10 that negative pole is connected with the emitter of triode VT8, one end is connected with the positive pole of polar capacitor C10, the resistance R22 that the other end is connected with the negative pole of polar capacitor C10, N pole is connected with the base stage of triode VT7 after resistance R24, the diode D8 that P pole is connected with the emitter of triode VT8, one end is connected with the N pole of diode D8, the resistance R23 that the other end is connected with the collector electrode of triode VT7, P pole is connected with the emitter of triode VT6 after resistance R25, the diode D9 that N pole is connected with the emitter of triode VT7, P pole is connected with the source electrode of field effect transistor MOS, the diode D10 that N pole is connected with the collector electrode of triode VT7, and positive pole is connected with the source electrode of field effect transistor MOS, the polar capacitor C12 that negative pole is connected with the collector electrode of triode VT7 after resistance R27 through inductance L in turn forms, the grounded collector of described triode VT6, the grid of described field effect transistor MOS is connected with the P pole of diode D9, the base stage of described triode VT8 and thermistor R18 and the tie point of resistance R21 jointly form the input that starts ICLC and are connected with power supply, the grounded collector of this triode VT8, the collector electrode of described triode VT7 and the drain electrode of field effect transistor MOS jointly form the output of startup ICLC and are connected with central processing unit.
Described low-voltage load light adjusting circuit is by triode VT4, triode VT is inverse, amplifier P2, unidirectional thyristor D8, N pole is connected with the base stage of triode VT after resistance R11, the diode D5 that P pole is connected with the emitter of triode VT4, positive pole is connected with the collector electrode of triode VT4 after resistance R13, the polar capacitor C7 that negative pole is connected with the emitter of triode VT5, positive pole is connected with the emitter of triode VT4 after resistance R12, the polar capacitor C6 that negative pole is connected with the emitter of triode VT5 after adjustable resistance R14, positive pole is connected with the positive pole of polar capacitor C6, the polar capacitor C8 of minus earth, P pole is connected with the positive pole of polar capacitor C8, the diode D6 that N pole is connected with the positive pole of amplifier P2, one end is connected with the emitter of triode VT5, the resistance R15 that the other end is connected with the anode of unidirectional thyristor D8, and P pole is connected with the P pole of diode D6 after resistance R18 through resistance R17 in turn, the diode D7 that N pole is connected with the output of amplifier P2 forms, the N pole of described diode D5 jointly forms the input of low-voltage load light adjusting circuit with the base stage of triode VT5 and is connected with central processing unit, the grounded collector of described triode VT5, the negative pole of described amplifier P2 is connected with the negative electrode of unidirectional thyristor D8, and the output of this amplifier P2 and the tie point of resistance R16 and resistance R17 form the output of low-voltage load light adjusting circuit jointly, the control end of described unidirectional thyristor D8 is connected with the adjustable end of adjustable resistance R8.
Described frequency-modulated beam receiving circuit is then by the filter circuit be connected with light-inductive device, and the differential amplifier circuit be connected with filter circuit forms; The output of described differential amplifier circuit is connected with central processing unit.
Described filter circuit is by triode VT1, diode D1, polar capacitor C3, negative pole is connected with the base stage of triode VT1 after resistance R2, the polar capacitor C1 that positive pole is connected with the P pole of diode D1 after resistance R1, positive pole is connected with the base stage of triode VT1, the polar capacitor C2 that negative pole is connected with the emitter of triode VT1 after inductance L, P pole is connected with the negative pole of polar capacitor C1 after resistance R5, the diode D2 that N pole is connected with the base stage of triode VT1, one end is connected with the N pole of diode D1, the resistance R3 that the other end is connected with the negative pole of polar capacitor C2, and one end is connected with the negative pole of polar capacitor C2, the other end and the positive pole of polar capacitor C3 jointly form the output of filter circuit and the resistance R4 be connected with differential amplifier circuit forms, the negative pole of described polar capacitor C1 as filter circuit input and be connected with light-inductive device, grounded collector, its emitter of described triode VT1 are connected with the negative pole of polar capacitor C3.
Described differential amplifier circuit is by triode VT2, triode VT3, amplifier P1, P pole is connected with the base stage of triode VT2 after resistance R7, the diode D3 that N pole is connected with the negative pole of polar capacitor C2 after resistance R4, one end is connected with the collector electrode of triode VT3, the resistance R6 that the other end is connected with the emitter of triode VT2, P pole is connected with the P pole of diode D3 after adjustable resistance R8, the diode D4 that N pole is connected with the negative pole of amplifier P1, positive pole is connected with the P pole of diode D4, the polar capacitor C5 that negative pole is connected with the output of amplifier P1 after resistance R10, positive pole is connected with the positive pole of amplifier P1, the polar capacitor C4 of ground connection while of after negative pole is connected with the collector electrode of triode VT2, and one end is connected with the positive pole of amplifier P1, the resistance R9 that the other end is connected with the output of amplifier P1 forms, the base stage of described triode VT3 is connected with the positive pole of polar capacitor C3, its emitter is connected with the N pole of diode D3, the output of described amplifier P1 is as the output of differential amplifier circuit.
For guaranteeing practical effect of the present invention, described light-inductive device preferentially adopts RA-1805NO type light-inductive device to realize; Infrared probe then adopts KR-P819 type infrared probe to realize; Process chip U then preferentially adopts TDA3047 integrated chip to realize simultaneously.
The present invention compared with prior art has the following advantages and beneficial effect:
(1) infrared signal receiving circuit of the present invention can be eliminated the mistake frame signal that infrared probe exports in the signal detected, also can suppress by rugged varying signal the pulse in signal, because this ensure that the signal that infrared probe detects can accurately be transferred to central processing unit.
(2) high electric current when startup ICLC of the present invention can export instantaneously to source current limits, when effectively preventing LED from opening, the central processing unit of control system punctures by height electric current, ensure that this control system stability in use.
(3) low-voltage load light adjusting circuit of the present invention controls by the pulse current in the control electric current that exports central processing unit, export the brightness of corresponding electric current to LED to regulate simultaneously, thus ensure that the brightness of LED can automatically adjust according to the change information of the brightness of the indoor of light-inductive device collection.
(4) frequency-modulated beam receiving circuit of the present invention can carry out anti-interference process to the luminance signal that light-inductive device exports, high-frequency interferencing signal in the luminance signal that can also prevent light-inductive device from exporting scurries into central processing unit, thus ensure that LED intelligent control system of the present invention carries out accuracy adjustment to the brightness of LED desk lamp.
(5) present invention employs light-inductive device, the stable performance of this light-inductive device, the scope of Information Monitoring is wide, can accurately gather the brightness in acquisition range.
(6) infrared probe that the present invention adopts can carry out the detection of wide-angle 180 °, and it has the advantages such as accuracy is high, sensitivity is strong, therefore, ensure that LED intelligent control system of the present invention can accurately be closed automatically to LED desk lamp.
(7) LED intelligent control system of the present invention, make LED desk lamp achieve automation brightness regulation, and can automatically close in unmanned, save electric energy greatly, and the useful life of LED desk lamp can be substantially increased, reduce use cost.
Accompanying drawing explanation
Fig. 1 is overall structure figure of the present invention.
Fig. 2 is the electrical block diagram of frequency-modulated beam receiving circuit of the present invention.
Fig. 3 is the electrical block diagram of low-voltage load light adjusting circuit of the present invention.
Fig. 4 is the electrical block diagram of startup ICLC of the present invention.
Fig. 5 is the electrical block diagram of infrared signal receiving circuit of the present invention.
Embodiment
Below in conjunction with embodiment, the present invention is described in further detail, but embodiments of the present invention are not limited thereto.
As shown in Figure 1, the present invention is primarily of central processing unit, light-inductive device, the display be all connected with central processing unit, infrared probe, power supply and LED, be serially connected in the infrared signal receiving circuit between infrared probe and central processing unit, be serially connected in the frequency-modulated beam receiving circuit between light-inductive device and central processing unit, be serially connected in the low-voltage load light adjusting circuit between central processing unit and LED, and be serially connected in the startup ICLC composition between power supply and central processing unit.Wherein, as shown in Figure 2, it is made up of filter circuit and differential amplifier circuit this frequency-modulated beam receiving circuit.
For guaranteeing reliability service of the present invention, described central processing unit preferentially adopts LTC3455 integrated chip, and the SEN pin of this LTC3455 integrated chip is connected with display.To be 12V direct voltage power for central processing unit through starting after ICLC limits high electric current described power supply.
As shown in Figure 2, described filter circuit by triode VT1, resistance R1, resistance R2, resistance R3, resistance R4, resistance R5, polar capacitor C1, polar capacitor C2, polar capacitor C3, diode D1, and diode D2 forms.
During connection, the negative pole of polar capacitor C1 is connected with the base stage of triode VT1 after resistance R2, positive pole is connected with the P pole of diode D1 after resistance R1.The positive pole of polar capacitor C2 is connected with the base stage of triode VT1, negative pole is connected with the emitter of triode VT1 after inductance L.The P pole of diode D2 is connected with the negative pole of polar capacitor C1 after resistance R5, N pole is connected with the base stage of triode VT1.One end of resistance R3 is connected with the N pole of diode D1, the other end is connected with the negative pole of polar capacitor C2.One end of resistance R4 is connected with the negative pole of polar capacitor C2, the other end jointly forms the output of filter circuit with the positive pole of polar capacitor C3 and is connected with differential amplifier circuit.The negative pole of described polar capacitor C1 as filter circuit input and be connected with light-inductive device; Grounded collector, its emitter of described triode VT1 are connected with the negative pole of polar capacitor C3.
Further, described differential amplifier circuit by triode VT2, triode VT3, amplifier P1, resistance R6, resistance R7, adjustable resistance R8, resistance R9, resistance R10, polar capacitor C4, polar capacitor C5, diode D3, and diode D4 forms.
During connection, the P pole of diode D3 is connected with the base stage of triode VT2 after resistance R7, N pole is connected with the negative pole of polar capacitor C2 after resistance R4.One end of resistance R6 is connected with the collector electrode of triode VT3, the other end is connected with the emitter of triode VT2.The P pole of diode D4 is connected with the P pole of diode D3 after adjustable resistance R8, N pole is connected with the negative pole of amplifier P1.
The positive pole of described polar capacitor C5 is connected with the P pole of diode D4, negative pole is connected with the output of amplifier P1 after resistance R10.The ground connection while of after the positive pole of polar capacitor C4 is connected with the positive pole of amplifier P1, negative pole is connected with the collector electrode of triode VT2.One end of resistance R9 is connected with the positive pole of amplifier P1, the other end is connected with the output of amplifier P1.The base stage of described triode VT3 is connected with the positive pole of polar capacitor C3, its emitter is connected with the N pole of diode D3; The output of described amplifier P1 as differential amplifier circuit output and be connected with the IN pin of LTC3455 integrated chip.
Operationally, the filter circuit of luminance signal in frequency-modulated beam receiving circuit of light-inductive device collection carries out signal anti-interference process in the present invention, and eliminates the harmonic wave in the luminance signal after process, guarantees the flatness of luminance signal.High-frequency signal in signal and low frequency signal are regulated by differential amplifier circuit by the luminance signal after being processed by filter circuit, then the luminance signal after adjustment are carried out amplifying rear output.
As shown in Figure 3, it is by triode VT4, and triode VT is inverse for described low-voltage load light adjusting circuit, amplifier P2, unidirectional thyristor D8, resistance R11, resistance R12, resistance R13, resistance R14, resistance R15, resistance R16, resistance R17, polar capacitor C6, polar capacitor C7, polar capacitor C8, diode D5, diode D6, and diode D7 forms.
During connection, the N pole of diode D5 is connected with the base stage of triode VT after resistance R11, P pole is connected with the emitter of triode VT4.The positive pole of polar capacitor C7 is connected with the collector electrode of triode VT4 after resistance R13, negative pole is connected with the emitter of triode VT5.The positive pole of polar capacitor C6 is connected with the emitter of triode VT4 after resistance R12, negative pole is connected with the emitter of triode VT5 after adjustable resistance R14.
The positive pole of described polar capacitor C8 is connected with the positive pole of polar capacitor C6, minus earth.The P pole of diode D6 is connected with the positive pole of polar capacitor C8, N pole is connected with the positive pole of amplifier P2.One end of resistance R15 is connected with the emitter of triode VT5, the other end is connected with the anode of unidirectional thyristor D8.The P pole of diode D7 is connected with the P pole of diode D6 after resistance R18 through resistance R17 in turn, N pole is connected with the output of amplifier P2.
The N pole of described diode D5 is connected with the C3455 integrated chip BST1 pin of LT; The C3455 integrated chip BST2 pin of the base stage LT of described triode VT5 is connected; The grounded collector of described triode VT5; The negative pole of described amplifier P2 is connected with the negative electrode of unidirectional thyristor D8, and the output of this amplifier P2 and the tie point of resistance R16 and resistance R17 form the output of low-voltage load light adjusting circuit jointly; The control end of described unidirectional thyristor D8 is connected with the adjustable end of adjustable resistance R8.
The present invention operationally, low-voltage load light adjusting circuit controls by the pulse current in the control electric current that exports central processing unit, export the brightness of corresponding electric current to LED to regulate simultaneously, thus ensure that the brightness of LED can automatically adjust according to the change information of the brightness of the indoor of light-inductive device collection.
As shown in Figure 4, it is by triode VT6, triode VT7, triode VT8 for described startup ICLC, field effect transistor MOS, thermistor R18, resistance R19, resistance R20, resistance R21, resistance R22, resistance R23, resistance R24, resistance R25, resistance R26, resistance R27, polar capacitor C9, polar capacitor C10, polar capacitor C11, polar capacitor C12, diode D8, diode D9, and diode D10 forms.
During connection, the positive pole of polar capacitor C11 is connected with the drain electrode of field effect transistor MOS after resistance R26, negative pole is connected with the base stage of triode VT6.The positive pole of polar capacitor C9 is connected with the positive pole of polar capacitor C11 after resistance R21 through thermistor R18 in turn, negative pole is connected with the base stage of triode VT8 after resistance R19.The positive pole of polar capacitor C10 is connected with the tie point of resistance R21 with thermistor R18 after resistance R20, negative pole is connected with the emitter of triode VT8.
One end of described resistance R22 is connected with the positive pole of polar capacitor C10, the other end is connected with the negative pole of polar capacitor C10.The N pole of diode D8 is connected with the base stage of triode VT7 after resistance R24, P pole is connected with the emitter of triode VT8.One end of resistance R23 is connected with the N pole of diode D8, the other end is connected with the collector electrode of triode VT7.The P pole of diode D9 is connected with the emitter of triode VT6 after resistance R25, N pole is connected with the emitter of triode VT7.The P pole of diode D10 is connected with the source electrode of field effect transistor MOS, N pole is connected with the collector electrode of triode VT7.The positive pole of polar capacitor C12 is connected with the source electrode of field effect transistor MOS, negative pole is connected with the collector electrode of triode VT7 after resistance R27 through inductance L in turn.
The grounded collector of described triode VT6; The grid of described field effect transistor MOS is connected with the P pole of diode D9; The base stage of described triode VT8 and thermistor R18 and the tie point of resistance R21 jointly form the input that starts ICLC and are connected with power supply, the grounded collector of this triode VT8; The collector electrode of described triode VT7 is connected with the VC pin of LTC3455 integrated chip; The drain electrode of described field effect transistor MOS is connected with the PV pin of LTC3455 integrated chip.
The present invention operationally, start ICLC to limit power supply flows to central processing unit high electric current when LED is opened, when the electric current held stationary inputted, inductance L just makes thermistor R18 short circuit, now, the electric current of ICLC stable output is started.If turn off power supply, this circuit then resets to the state of startup by field effect transistor MOS.The present invention, described thermistor R18 is Metal Oxide Varistor.
As shown in Figure 5, it is by process chip U for described infrared signal receiving circuit, triode VT9, triode VT10, resistance R28, adjustable resistance R29, resistance R30, resistance R31, resistance R32, resistance R33, resistance R34, polar capacitor C13, polar capacitor C14, polar capacitor C15, polar capacitor C16, polar capacitor C17, diode D11, diode D12, and diode D13 forms.
During connection, the positive pole of polar capacitor C13 is connected with the N pole of diode D11 after resistance R28, negative pole is connected with the emitter of triode VT9 after resistance R30.The positive pole of polar capacitor C17 is connected with the N pole of diode D11, negative pole is connected with the base stage of triode VT9 after adjustable resistance R29.One end of resistance R31 is connected with the SC pin of process chip U, the other end is connected with the collector electrode of triode VT9.The negative pole of polar capacitor C14 is connected with the PWM pin of process chip U, positive pole is connected with the adjustable end of adjustable resistance R29.The P pole of diode D12 is connected with the P pole of diode D11 after resistance R32, N pole is connected with the SW pin of process chip U.
The negative pole of described polar capacitor C15 is connected with the SHF pin of process chip U, positive pole is connected with the FW pin of process chip U.The P pole of diode D13 is connected with the SEN pin of process chip U after resistance R33, N pole is connected with the emitter of triode VT10.The positive pole of polar capacitor C16 is connected with the OUT pin of process chip U, negative pole is connected with the base stage of triode VT10 after resistance R34.
The VIN pin of described process chip U is connected with the negative pole of polar capacitor C14, its GND pin ground connection; The grounded collector of described triode VT10; The positive pole of described polar capacitor C13 as infrared signal receiving circuit input and be connected with infrared probe; The negative pole of described polar capacitor C16 is connected as infrared signal receiving circuit output and with the DIM pin of LTC3455 integrated chip.
The present invention operationally, infrared signal receiving circuit can be eliminated the mistake frame signal that infrared probe exports in the signal detected, also can suppress by rugged varying signal the pulse in signal, because this ensure that the signal that infrared probe detects can accurately be transferred to central processing unit.For better implementing the present invention, described process chip U then preferentially have employed the TDA3047 integrated chip with high stability and realizes.
During operation, described light-inductive device preferentially adopts RA-1805NO type light-inductive device to realize; This light-inductive device for gathering the monochrome information in grease chamber, and by the luminance information signal collected through frequency-modulated beam receiving circuit carry out signal anti-interference process and amplify regulate after give central processing unit.Brightness reference point is set with in described central processing unit, the luminance signal received is converted to data value and compares with brightness reference point by this central processing unit, and regulate through the brightness of low-voltage load light adjusting circuit to LED desk lamp according to the corresponding electric current that controls of the result output of comparison, the brightness maintenance making LED desk lamp is consistent with the brightness reference point set in central processing unit.
Meanwhile, described infrared probe is 180 ° of wide-angle infrared probes, and this infrared probe can accurately detect indoor constantly, and by the information detected by being transferred to central processing unit after the process of infrared signal receiving circuit.When infrared ray probe detection is to indoor nobody time, and by this information transmission to central processing unit, at this moment central processing unit just can automatically stop exporting control electric current after information analysis, and this LED is just closed, and now LED also can return to rebooting status.
Wherein, described display for show the intrinsic brilliance value of LED, central processing unit built-in with reference to brightness value, and the luminance difference with reference to brightness value that the intrinsic brilliance value of LED is built-in with central processing unit, is convenient to the brightness case that people understand indoor.For guaranteeing reliability service of the present invention, described infrared probe then adopts KR-P819 type infrared probe to realize.
As mentioned above, just the present invention can well be realized.
Claims (10)
1. the multi-functional intelligent control system of LED, it is characterized in that, primarily of central processing unit, light-inductive device, the display be all connected with central processing unit, infrared probe, power supply and LED, be serially connected in the infrared signal receiving circuit between infrared probe and central processing unit, be serially connected in the frequency-modulated beam receiving circuit between light-inductive device and central processing unit, be serially connected in the low-voltage load light adjusting circuit between central processing unit and LED, and be serially connected in the startup ICLC composition between power supply and central processing unit.
2. the multi-functional intelligent control system of a kind of LED according to claim 1, it is characterized in that, described infrared signal receiving circuit is by process chip U, triode VT9, triode VT10, diode D11, positive pole is connected with the N pole of diode D11 after resistance R28, the polar capacitor C13 that negative pole is connected with the emitter of triode VT9 after resistance R30, positive pole is connected with the N pole of diode D11, the polar capacitor C17 that negative pole is connected with the base stage of triode VT9 after adjustable resistance R29, one end is connected with the SC pin of process chip U, the resistance R31 that the other end is connected with the collector electrode of triode VT9, negative pole is connected with the PWM pin of process chip U, the polar capacitor C14 that positive pole is connected with the adjustable end of adjustable resistance R29, P pole is connected with the P pole of diode D11 after resistance R32, the diode D12 that N pole is connected with the SW pin of process chip U, negative pole is connected with the SHF pin of process chip U, the polar capacitor C15 that positive pole is connected with the FW pin of process chip U, P pole is connected with the SEN pin of process chip U after resistance R33, the diode D13 that N pole is connected with the emitter of triode VT10, and positive pole is connected with the OUT pin of process chip U, the polar capacitor C16 that negative pole is connected with the base stage of triode VT10 after resistance R34 forms, the VIN pin of described process chip U is connected with the negative pole of polar capacitor C14, its GND pin ground connection, the grounded collector of described triode VT10, the positive pole of described polar capacitor C13 as infrared signal receiving circuit input and be connected with infrared probe, the negative pole of described polar capacitor C16 is as infrared signal receiving circuit output and be connected with central processing unit.
3. the multi-functional intelligent control system of a kind of LED according to claim 2, it is characterized in that, described startup ICLC is by triode VT6, triode VT7, triode VT8, field effect transistor MOS, positive pole is connected with the drain electrode of field effect transistor MOS after resistance R26, the polar capacitor C11 that negative pole is connected with the base stage of triode VT6, positive pole is connected with the positive pole of polar capacitor C11 after resistance R21 through thermistor R18 in turn, the polar capacitor C9 that negative pole is connected with the base stage of triode VT8 after resistance R19, positive pole is connected with the tie point of resistance R21 with thermistor R18 after resistance R20, the polar capacitor C10 that negative pole is connected with the emitter of triode VT8, one end is connected with the positive pole of polar capacitor C10, the resistance R22 that the other end is connected with the negative pole of polar capacitor C10, N pole is connected with the base stage of triode VT7 after resistance R24, the diode D8 that P pole is connected with the emitter of triode VT8, one end is connected with the N pole of diode D8, the resistance R23 that the other end is connected with the collector electrode of triode VT7, P pole is connected with the emitter of triode VT6 after resistance R25, the diode D9 that N pole is connected with the emitter of triode VT7, P pole is connected with the source electrode of field effect transistor MOS, the diode D10 that N pole is connected with the collector electrode of triode VT7, and positive pole is connected with the source electrode of field effect transistor MOS, the polar capacitor C12 that negative pole is connected with the collector electrode of triode VT7 after resistance R27 through inductance L in turn forms, the grounded collector of described triode VT6, the grid of described field effect transistor MOS is connected with the P pole of diode D9, the base stage of described triode VT8 and thermistor R18 and the tie point of resistance R21 jointly form the input that starts ICLC and are connected with power supply, the grounded collector of this triode VT8, the collector electrode of described triode VT7 and the drain electrode of field effect transistor MOS jointly form the output of startup ICLC and are connected with central processing unit.
4. the multi-functional intelligent control system of a kind of LED according to claim 3, it is characterized in that, described low-voltage load light adjusting circuit is by triode VT4, triode VT is inverse, amplifier P2, unidirectional thyristor D8, N pole is connected with the base stage of triode VT after resistance R11, the diode D5 that P pole is connected with the emitter of triode VT4, positive pole is connected with the collector electrode of triode VT4 after resistance R13, the polar capacitor C7 that negative pole is connected with the emitter of triode VT5, positive pole is connected with the emitter of triode VT4 after resistance R12, the polar capacitor C6 that negative pole is connected with the emitter of triode VT5 after adjustable resistance R14, positive pole is connected with the positive pole of polar capacitor C6, the polar capacitor C8 of minus earth, P pole is connected with the positive pole of polar capacitor C8, the diode D6 that N pole is connected with the positive pole of amplifier P2, one end is connected with the emitter of triode VT5, the resistance R15 that the other end is connected with the anode of unidirectional thyristor D8, and P pole is connected with the P pole of diode D6 after resistance R18 through resistance R17 in turn, the diode D7 that N pole is connected with the output of amplifier P2 forms, the N pole of described diode D5 jointly forms the input of low-voltage load light adjusting circuit with the base stage of triode VT5 and is connected with central processing unit, the grounded collector of described triode VT5, the negative pole of described amplifier P2 is connected with the negative electrode of unidirectional thyristor D8, and the output of this amplifier P2 and the tie point of resistance R16 and resistance R17 form the output of low-voltage load light adjusting circuit jointly, the control end of described unidirectional thyristor D8 is connected with the adjustable end of adjustable resistance R8.
5. the multi-functional intelligent control system of a kind of LED according to claim 4, is characterized in that, described frequency-modulated beam receiving circuit is then by the filter circuit be connected with light-inductive device, and the differential amplifier circuit be connected with filter circuit forms; The output of described differential amplifier circuit is connected with central processing unit.
6. the multi-functional intelligent control system of a kind of LED according to claim 5, it is characterized in that, described filter circuit is by triode VT1, diode D1, polar capacitor C3, negative pole is connected with the base stage of triode VT1 after resistance R2, the polar capacitor C1 that positive pole is connected with the P pole of diode D1 after resistance R1, positive pole is connected with the base stage of triode VT1, the polar capacitor C2 that negative pole is connected with the emitter of triode VT1 after inductance L, P pole is connected with the negative pole of polar capacitor C1 after resistance R5, the diode D2 that N pole is connected with the base stage of triode VT1, one end is connected with the N pole of diode D1, the resistance R3 that the other end is connected with the negative pole of polar capacitor C2, and one end is connected with the negative pole of polar capacitor C2, the other end and the positive pole of polar capacitor C3 jointly form the output of filter circuit and the resistance R4 be connected with differential amplifier circuit forms, the negative pole of described polar capacitor C1 as filter circuit input and be connected with light-inductive device, grounded collector, its emitter of described triode VT1 are connected with the negative pole of polar capacitor C3.
7. the multi-functional intelligent control system of a kind of LED according to claim 6, it is characterized in that, described differential amplifier circuit is by triode VT2, triode VT3, amplifier P1, P pole is connected with the base stage of triode VT2 after resistance R7, the diode D3 that N pole is connected with the negative pole of polar capacitor C2 after resistance R4, one end is connected with the collector electrode of triode VT3, the resistance R6 that the other end is connected with the emitter of triode VT2, P pole is connected with the P pole of diode D3 after adjustable resistance R8, the diode D4 that N pole is connected with the negative pole of amplifier P1, positive pole is connected with the P pole of diode D4, the polar capacitor C5 that negative pole is connected with the output of amplifier P1 after resistance R10, positive pole is connected with the positive pole of amplifier P1, the polar capacitor C4 of ground connection while of after negative pole is connected with the collector electrode of triode VT2, and one end is connected with the positive pole of amplifier P1, the resistance R9 that the other end is connected with the output of amplifier P1 forms, the base stage of described triode VT3 is connected with the positive pole of polar capacitor C3, its emitter is connected with the N pole of diode D3, the output of described amplifier P1 is as the output of differential amplifier circuit.
8. the multi-functional intelligent control system of a kind of LED according to claim 7, is characterized in that, described light-inductive device is RA-1805NO type light-inductive device.
9. the multi-functional intelligent control system of a kind of LED according to claim 8, is characterized in that, described infrared probe is KR-P819 type infrared probe.
10. the multi-functional intelligent control system of a kind of LED according to claim 9, is characterized in that, described process chip U is TDA3047 integrated chip.
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| CN201510957248.1A CN105430806A (en) | 2015-12-18 | 2015-12-18 | Multifunctional intelligent control system for LED lamp |
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