CN201039543Y

CN201039543Y - Lighting controller

Info

Publication number: CN201039543Y
Application number: CNU2007201476928U
Authority: CN
Inventors: 张保鸣
Original assignee: Shanghai Zhitong Electric Coltd
Current assignee: Shanghai Zhitong Electric Coltd
Priority date: 2007-04-26
Filing date: 2007-04-26
Publication date: 2008-03-19
Anticipated expiration: 2017-04-26

Abstract

The utility model discloses a lightening controller, comprising a manual controlling triggering circuit, an infrared remote-controlling triggering circuit, a long-distance online controlling triggering circuit used for online control, a singe-sheet machine, a main driving machine and an actuating switch circuit, wherein, the manual controlling triggering circuit, the infrared remote-controlling triggering circuit and the long-distance online controlling triggering circuit are respectively connected with the single-sheet machine which controls the actuating switch circuit through the main driving machine. While meeting the controlling requirements of the manual control and the infrared remote-control, the utility model also realizes online control, thus meeting long-distance control for people. The utility model is further convenient for daily work and life of people.

Description

Lighting controller

Technical field

The utility model relates to a kind of lighting controller.

Background technology

We use lighting controller in living or working at present, and some can manually be controlled, and can realize in-plant manual control; Some can be controlled by infrared remote control, can realize the closely interior closely remote control control of infrared ray controlled range; Also some can be controlled by long-distance on-line, it can be realized by the data wire transmission manner, control range is far longer than infrared ray control scope, can be in the scope inner control in about 200 meters, and can show that the illuminating lamp in concrete which room is in work by network and physical circuit, the lamp in which room is closed, but no matter adopt above-mentioned which kind of concrete control mode, it is very single to be still control mode.

Along with improving constantly of people's quality of life, people may need a kind of controller to have multiple control modes simultaneously, even above-mentioned single control mode adapt to far from present people demand, have very much limitation.

The utility model content

The technical problems to be solved in the utility model provides a kind of lighting controller.

Above-mentioned technical problem solves by following method:

A kind of lighting controller, include manual control triggering electric circuit, infrared remote control circuits for triggering and be used for long-distance on-line control triggering electric circuit, the single-chip microcomputer of network control, master driver, with the execution switching circuit, described manual control triggering electric circuit, described infrared remote control circuits for triggering and described long-distance on-line control triggering electric circuit are connected described single-chip microcomputer respectively, and described single-chip microcomputer is controlled described execution switching circuit by described master driver.

Described manual control triggering electric circuit includes at least two buttons and first driver, and described button one end connects described single-chip microcomputer, and the other end connects described single-chip microcomputer by first driver.

Described infrared remote control circuits for triggering include infrared remote receiver, described infrared remote receiver connects described execution switching circuit by described single-chip microcomputer.

Described single-chip microcomputer also is connected with display lamp indicating circuit and sound instruction circuit.

Described display lamp indicating circuit includes light-emitting diode, and described light-emitting diode connects described single-chip microcomputer.

Described sound instruction circuit includes buzzer, first diode, first resistance and first triode, described single-chip microcomputer is connected the collector electrode of described triode by described first resistance and described first diode forward, the emitter of described first triode connects described master driver, described first diode described buzzer in parallel.

Also be connected with first circuit between described single-chip microcomputer and the described execution switching circuit, described first circuit comprises first resistance, second resistance and second diode, described first resistance and second resistance form bleeder circuit, and described bleeder circuit connects described execution switching circuit by second diode that is connected in series.

Also be connected with second circuit between described single-chip microcomputer and the described Long-distance Control circuits for triggering, described second circuit comprises the 3rd resistance and second triode, described single-chip microcomputer connects the base stage of described second triode by described the 3rd resistance, and the emitter of described second triode connects described executive circuit.

Described execution switching circuit includes at least two relays, and described single-chip microcomputer connects described relay by described master driver.

Described long-distance on-line control triggering electric circuit includes data processor, and described data processor provides remote control signal for described single-chip microcomputer.

The beneficial effects of the utility model are: because the utility model includes manual control triggering electric circuit, infrared remote control circuits for triggering and the long-distance on-line control triggering electric circuit that is used for network control, single-chip microcomputer, master driver, with the execution switching circuit, described manual control triggering electric circuit, described infrared remote control circuits for triggering are connected described single-chip microcomputer respectively with described long-distance on-line control triggering electric circuit, described single-chip microcomputer is controlled described execution switching circuit by described master driver, not only can realize manual control, closely infrared remote control control, also can show longer-distance networking control, such as upstairs and mutual control downstairs, and long-distance on-line control is bright by the lamp that network and physical circuit also can very intuitively demonstrate concrete which room, the lamp house in which room is closed, convenient people's work and life.

Description of drawings

Fig. 1 is the theory diagram of the utility model first embodiment;

Fig. 2 is the physical circuit figure of power circuit among Fig. 1;

Fig. 3 is manual control triggering electric circuit and long-distance on-line control circuit connecting circuit figure among Fig. 1;

Fig. 4 is the physical circuit figure of infrared remote control circuits for triggering among Fig. 1;

Fig. 5 carries out switching circuit physical circuit figure among Fig. 1;

Fig. 6 is the connecting circuit figure of display lamp indicating circuit and sound instruction circuit among another embodiment of the utility model.

Embodiment

Below in conjunction with drawings and the specific embodiments the utility model is described in further details.

As shown in Figure 1, a kind of lighting controller comprises voltage-stabilized power supply circuit 1, manual control triggering electric circuit 2, infrared remote control circuits for triggering 3, long-distance on-line control triggering electric circuit 4, single-chip microcomputer U1, master driver 5 and carries out switching circuit 6.Described manual control triggering electric circuit 2, infrared remote control circuits for triggering 3 and described long-distance on-line control triggering electric circuit 4 are controlled described master driver 5 by described single-chip microcomputer U1 and are driven described execution switching circuit 6 actions, and described power circuit 1 provides power supply for entire circuit.

With reference to Fig. 2, as preferred implementation, described power circuit 1 is a voltage stabilizing circuit, comprise transformer T1, pressurizer U2, piezo-resistance R11, the uncontrollable rectification circuit of single-phase bridge, the uncontrollable rectification circuit of described single-phase bridge is made up of the first diode D1, the second diode D2, the 3rd diode D3 and the 4th diode D4, and described power circuit 1 also comprises first capacitor C 1, second capacitor C 2, the 3rd capacitor C 3 and the 4th capacitor C 4.Described 220V power supply through piezo-resistance R11 after through the uncontrollable rectification circuit rectification of single-phase bridge, output 12V voltage, again through after

first capacitor C

1 and 2 filtering of second capacitor C through pressurizer U2 voltage stabilizing, through the

3rd capacitor C

3 and 4 filtering of the 4th capacitor C, obtain the 5V direct voltage.

With reference to Fig. 3, described manual control triggering electric circuit 2 comprises first pushbutton unit 7,

second pushbutton unit

8 and 9 three pushbutton units of the 3rd pushbutton unit, also comprise the one seven tunnel power drive chip U3, described first pushbutton unit 7 comprises the button S1-S8 that is connected in parallel, described second pushbutton unit 8 comprises the button S9-S16 that is connected in parallel, and described the 3rd pushbutton unit 9 comprises the button S17-S24 that is connected in parallel; Described first pushbutton unit, 7 one ends connect first control input end of described single-chip microcomputer U1, and the other end connects first control input end of described seven tunnel power drive chip U3; One end of described second pushbutton unit 8 connects second control input end of described single-chip microcomputer U1, and the other end connects second control input end of described seven tunnel power drive chip U3; One end of described the 3rd pushbutton unit 9 connects the 3rd control input end of described single-chip microcomputer U1, the other end connects the 3rd control input end of described seven tunnel power drive chip U3, and the control output end of described seven tunnel power drive chip U3 connects the 4th control input end of described single-chip microcomputer U1.

With reference to Fig. 4, described infrared remote control circuits for triggering 3 comprise infrared remote receiver U4, first resistance R 1, the 5th capacitor C 5 and the 6th capacitor C 6.Please in the lump with reference to Fig. 3, the 5V direct voltage of described voltage-stabilized power supply circuit 1 output connects first resistance R 1, and by providing power supply for infrared remote receiver U4 after the

5th capacitor C

5 and 6 filtering of the 6th capacitor C, described infrared remote receiver U4 signal receiving end receives infrared signal, and this signal is transferred to described single-chip microcomputer U1, for it provides the infrared remote control triggering signal.

Referring again to Fig. 3, described long-distance on-line control triggering electric circuit 4 comprises data processor M1, the first triode VT1, second resistance R 2 and plug connector J1.Described data processor M1 is by forms data line or ground wire receiving remote control signal cluster, to connect the emitter of the first triode VT1 after this signal processing by the data-interface of plug connector J1, the base stage of the described first triode VT1 connects described single-chip microcomputer U1 by second resistance R 2, for described single-chip microcomputer U1 provides the control triggering signal, described power circuit 1 provides 12V power supply for described plug connector J1.

Please refer to Fig. 3, Fig. 4, described master driver 5 is the two seven tunnel power drive chip U5;

With reference to Fig. 5, described execution switching circuit 6 includes six relay K 1-K6.Described single-chip microcomputer U1 provides control signal for the two seven tunnel power drive chip U5, and described the two seven tunnel power drive chip U5 receive the control signal of described single-chip microcomputer U1 and connect described relay K 1-K6 to drive load by described plug connector J1.

Introduce manual control triggering electric circuit and operation principle below:

By next button, described button is level signal of a pin input of described single-chip microcomputer U1, because the described button other end connects described the one seven tunnel power drive chip U3, be that described single-chip microcomputer U1 imports another level signal by described the one seven tunnel power drive chip U3 again, described single-chip microcomputer U1 goes up and produces level difference value, control the corresponding actuating of relay by the described first power drive chip U3, thereby the corresponding load of control opens or closes.

In like manner, press different buttons, it inputs to the different level signal of described single-chip microcomputer U1, produces different level difference values, control the different actuatings of relay by described the two seven tunnel power drive chip U5, thereby the control different loads opens or closes.

For the infrared remote control circuits for triggering:

Described infrared remote receiver U4 receives infrared signal, to input to described single-chip microcomputer U1 after this infrared signal conversion, described single-chip microcomputer U1 connects the different pins of described the 2nd seven tunnel power drive chip U5, is its input control signal, thereby drive the different actuating of relay, control different loads.

For the long-distance on-line control triggering electric circuit:

Signal is transferred to described data processor M1 by forms data line and ground wire, described data processor M1 transforms the back with described data-signal and by the data-interface of described plug connector J1 control signal is imported, the control signal of described input provides control signal through the described first triode VT1 for described single-chip microcomputer U1, described single-chip microcomputer U1 drives the different pins of described the 2nd seven tunnel power drive chip U5, thereby drive the different actuating of relay, control different loads.

With reference to Fig. 6, for guaranteeing the forward flow of electric current, described single-chip microcomputer U1 output control terminal also is connected with the bleeder circuit of being made up of the 3rd resistance R 3 and the 4th resistance R 4, described bleeder circuit connects the network output interface by the 5th diode D5, with the output of realization data-signal, thereby the output that realizes networking is controlled.

Refer again to Fig. 1, as preferred implementation, the control output end of described single-chip microcomputer U1 also is connected with display lamp indicating circuit 10.

Referring again to Fig. 6, described display lamp indicating circuit 10 includes the first display lamp unit 11,13 3 the display lamp unit in the second display lamp unit 12 and the 3rd display lamp unit, the described first display lamp unit 11 comprises the LED lamp LED1-LED8 that is connected in parallel, the described second display lamp unit 12 comprises the LED lamp LED9-LED16 that is connected in parallel, and described the 3rd display lamp unit 13 comprises the LED lamp LED17-LED24 that is connected in parallel.The described first display lamp unit 11 1 ends connect the 5th control input end of described single-chip microcomputer U1 by the second triode VT2, and the other end connects first control input end of pseudo-ginseng road power drive chip U5; One end of the described second display lamp unit 12 connects the 6th control input end of described single-chip microcomputer U1 by the 3rd triode VT3, and the other end connects second control input end of described the 2nd seven tunnel power drive chip U5; One end of described the 3rd display lamp unit 13 connects the 7th control input end of described single-chip microcomputer U1 by the 4th triode VT4, the other end connects the 3rd control input end of described pseudo-ginseng road power drive chip U5, and the control output end of described the 2nd seven tunnel power drive chip U5 connects the 8th control input end of described single-chip microcomputer U1.

Press different buttons, for described single-chip microcomputer U1 imports different control signals, it is bright that described single-chip microcomputer U1 drives different LED lamps, and different LED lamps and the corresponding setting of different loads can make that the user is very directly perceived to see for which loaded work piece.

Refer again to Fig. 1, as preferred implementation, described single-chip microcomputer U1 also is connected with sound instruction circuit 14.

Referring again to Fig. 6, described sound instruction circuit 14 comprises buzzer Y1, the 6th diode D6 and the 5th triode VT5, described the 6th diode D6 and described single-chip microcomputer U1 are connected the collector electrode of described the 5th triode VT5, described the 6th diode D6 described buzzer Y1 in parallel by described the 5th resistance R 5 and described the 6th diode D6 forward.

After pressing the button, be single-chip microcomputer U1 input control signal, described single-chip microcomputer U1 drives described buzzer Y1 sounding, points out which loaded work piece, more convenient to use, hommization.

Described the one seven tunnel power drive chip U3, the two seven tunnel power drive chip U5, pseudo-ginseng road power drive chip U5 can be seven tunnel power drive chips of ULN2003 for model, can certainly be the chip for driving of other model.

The utility model is not limited to above-mentioned preferred forms; anyone can draw other various forms of products under enlightenment of the present utility model; no matter but on its shape or structure, do any variation; every have identical with a application or akin technical scheme, all drops within the protection range of the present utility model.

Claims

1. lighting controller, it is characterized in that, include manual control triggering electric circuit, infrared remote control circuits for triggering and be used for long-distance on-line control triggering electric circuit, the single-chip microcomputer of network control, master driver, with the execution switching circuit, described manual control triggering electric circuit, described infrared remote control circuits for triggering and described long-distance on-line control triggering electric circuit are connected described single-chip microcomputer respectively, and described single-chip microcomputer is controlled described execution switching circuit by described master driver.

2. lighting controller according to claim 1 is characterized in that: described manual control triggering electric circuit includes at least two buttons and first driver, and described button one end connects described single-chip microcomputer, and the other end connects described single-chip microcomputer by first driver.

3. lighting controller according to claim 1 is characterized in that: described infrared remote control circuits for triggering include infrared remote receiver, described infrared remote receiver connects described execution switching circuit by described single-chip microcomputer.

4. according to each described lighting controller among the claim 1-3, it is characterized in that: described single-chip microcomputer also is connected with display lamp indicating circuit and sound instruction circuit.

5. lighting controller according to claim 4 is characterized in that: described display lamp indicating circuit includes light-emitting diode, and described light-emitting diode connects described single-chip microcomputer.

6. lighting controller according to claim 4, it is characterized in that: described sound instruction circuit includes buzzer, first diode, first resistance and first triode, described single-chip microcomputer is connected the collector electrode of described triode by described first resistance and described first diode forward, the emitter of described first triode connects described master driver, described first diode described buzzer in parallel.

7. lighting controller according to claim 1, it is characterized in that: also be connected with first circuit between described single-chip microcomputer and the described execution switching circuit, described first circuit comprises first resistance, second resistance and second diode, described first resistance and second resistance form bleeder circuit, and described bleeder circuit connects described execution switching circuit by second diode that is connected in series.

8. lighting controller according to claim 1, it is characterized in that: also be connected with second circuit between described single-chip microcomputer and the described Long-distance Control circuits for triggering, described second circuit comprises the 3rd resistance and second triode, described single-chip microcomputer connects the base stage of described second triode by described the 3rd resistance, and the emitter of described second triode connects described executive circuit.

9. lighting controller according to claim 1 is characterized in that: described execution switching circuit includes at least two relays, and described single-chip microcomputer connects described relay by described master driver.

10. lighting controller according to claim 1 is characterized in that: described long-distance on-line control triggering electric circuit includes data processor, and described data processor provides remote control signal for described single-chip microcomputer.