KR101203909B1 - Apparatus for controlling sensor lamps and method thereof - Google Patents

Abstract

The present invention relates to a sensor lighting control device and a control method using the same, a first sensing unit for outputting a first signal generated from a fluid, a second sensing unit for outputting a second signal generated from the fluid, the first A control unit for controlling a signal received from the signal and the second signal and an output signal; and a load control switch unit for controlling an on / off state of a lighting lamp in response to an output signal of the control unit. Output to the load control switch unit for one hour, and includes the load control switch unit for the second signal for a second time after the first time is exceeded.

Description

Apparatus for controlling sensor lamps and method

The present invention relates to a control device and a control method using the same, and in particular, even if the fluid is out of the sensing range of the sensor or in a blind spot, the sound signal generated from the fluid can be detected by a differentiated algorithm to control the lighting time of the lamp. It relates to a sensor lighting control device and a control method using the same.

In general, the sensor light is installed in a place that requires temporary lighting, such as an apartment entrance, warehouse or meeting room to automatically turn on or off the light depending on whether the fluid is detected. These sensor lamps are for efficient use of electrical energy, and use an infrared sensor or a microwave sensor to detect heat or fluid motion generated from the fluid, thereby lighting the lamp for a predetermined time.

An example of a technique for a sensor lamp to which the infrared sensor is applied is shown in FIG. 1. 1 is a schematic block diagram of a sensor lamp control apparatus according to the prior art.

As shown in FIG. 1, a control device for controlling a lighting device using an infrared sensor includes a human body sensing circuit 1, an output contact 2, an anti-reverse diode 3, an input contact 4, and a photo die solution 5. And triac (6).

The human body sensing circuit unit 1 detects a passenger and operates for a predetermined time by a day / night selection mode and a pre-input timer. The output contact 2 is located at the output of the human body sensing circuit unit 1 and branches at least two or more outputs to other human body sensing circuit means. The anti-reverse diode 3 is connected in parallel with the output contact 2 to output an electrical signal for connecting the power to other circuit terminals in close proximity, and to transfer the current in one direction to prevent the flow of current in the reverse direction .

The input contact section 4 is connected to the output terminal of the reverse protection diode 3 and is connected to feed back the output line of the other human body sensing circuit means to the input line to output an electrical signal. The photo die solution 5 is activated in accordance with the output of the anti-reverse diode 3 and the output of the input contact portion 4 to output a lamp lighting signal. The triac 6 is connected to the output terminal of the photo die liquid 5 to light the lamp by the switching action of the photo die liquid 5.

The conventional sensor lamp control device automatically turns on the lamp when the entry of the fluid is detected, and turns off the lamp when the set time is exceeded. However, such a sensor lamp has a problem that it is automatically turned off when the fluid cannot be detected even if the fluid does not go out of the operating range of the infrared sensor. In addition, since the infrared sensor detects infrared rays emitted from the fluid, when the temperature around the sensor is high, the fluid detection performance is slowed down, and the sensing performance is increased depending on the contamination of the Fresnel lens used by being exposed to the air. The problem is that it is not uniform.

Therefore, in order to solve these problems, a sensor lamp that employs a microwave sensor has recently been used. The microwave sensor has an advantage of excellent sensing characteristics compared to an infrared sensor by using a radio wave, and can penetrate a non-metallic object to detect internal movement. However, the sensor lamps employing the microwave sensor are difficult to set an accurate sensing area due to the characteristics of radio waves, and because the sensing characteristics of the sensor are excellent, not only a fluid to be detected but also a ventilation fan such as an object composed of a certain amount or more of density, There is a problem that there are many malfunctions because it also reacts to the movement of insects and trees. In addition, the sensor lamp has a problem that a rectangular area that cannot be detected by the microwave sensor exists when the microwave sensor is used with a low detection performance.

An object of the present invention is to solve the problems described above, by reducing the malfunction of the sensor by continuously using a sensor for detecting the change in the wavelength of the fluid and a sensor for detecting the sound signal, such as lighting to meet the needs of the fluid It is to provide a sensor lamp control device that can adjust the lighting time and a control method using the same.

In addition, the object of the present invention is to build a variety of functions than the conventional sensor lighting control products, the power control capacity is superior to the maximum 4KW, the product size by developing to minimize the size of the entire product to less than 1/2 of the basic products It is to provide a sensor lighting control device and a control method using the same that can be supplied to the market at a low product cost by reducing the production cost to less than half.

In addition, an object of the present invention is to provide a sensor lamp control device and a control method using the same that can prevent the malfunction of the sensor lamp due to thermal and electrical sparks that may occur due to the triac and the relay.

In order to achieve the above object, the controller for controlling a sensor lamp according to the first embodiment of the present invention includes a first sensing unit outputting a first signal generated from a fluid, and a second sensing unit outputting a second signal generated from the fluid. And a load control switch unit configured to control an on / off state of a lamp in response to an output signal of the controller and a control unit controlling a signal outputted by receiving the first signal and the second signal. And outputting one signal to the load control switch for a first time, and outputting the second signal to the load control switch for a second time after the first time is exceeded.

In addition, according to the sensor lamp control apparatus according to the second embodiment of the present invention, the second sensing unit is generated from the fluid when the lamp is turned on in accordance with the first signal of the first sensing unit is turned off It is characterized by outputting two signals.

In addition, according to the sensor lighting control device according to a second embodiment of the present invention, the first detection unit is a first sensor for detecting a first signal generated from the fluid, a first amplifier for amplifying the first signal And a first discriminating unit determining the signal input to the controller by controlling and outputting the amplified first signal.

In addition, according to the sensor lighting control device according to the second embodiment of the present invention, the control unit operates in the normal mode irrespective of the change in the illumination of the outside of the first sensing unit, or the first night mode and By operating in the second night mode is characterized in that for adjusting the signal input to the load control switch unit.

In addition, according to the sensor lighting control apparatus according to the second embodiment of the present invention, the control unit outputs a signal according to the change in the illumination of the outside of the first sensing unit, and outputs a signal according to the change of sound outside the second sensing unit It is characterized by outputting.

In addition, according to the sensor lighting control device according to a second embodiment of the present invention, the second sensing unit is a second sensor unit for detecting a second signal generated from the fluid, a second amplification unit for amplifying the second signal And a second discrimination unit which determines the signal input to the controller by controlling and outputting the amplified second signal.

In addition, according to the sensor lighting control device according to the second embodiment of the present invention, the load control switch unit includes a triac (triac) and a relay (Relay), the triac and the relay operation time of on / off This is characterized by different things.

In addition, according to the sensor lighting control device according to the second embodiment of the present invention, when the load control switch unit is turned on, the triac first operates, and when the load control switch unit is turned off, the relay It is characterized in that the first operation.

According to a control method of a sensor lamp according to an embodiment of the present invention to achieve the above object, i) outputting a first signal sensing the fluid from the first sensing unit to turn on the lamp for a first time, ii) Determining whether the first time is exceeded by a controller when the fluid is out of the sensing distance of the first sensing unit in step iii); and iii) load when the first time is exceeded by step ii). Turning off the lamp from the control switch unit; i) determining whether the operation delay setting time of the control unit has been exceeded while the lamp is turned off; and i) exceeding the operation delay setting time in step iii). Determining whether or not the second time of the controller is exceeded; i) detecting the fluid from the second sensing unit when the second time is within the second time in step iii). Determining whether the second signal is outputted; and iii) lighting the lamp from the load control switch unit when the second signal is output in the step iii).

In addition, according to the control method of the sensor light according to an embodiment of the present invention, after the step iii) determining whether the second signal is continuously output from the second sensing unit and if the second signal is still output And turning on the lamp from the load control switch and turning off the lamp when the fluid is outside the detection range of the second detector.

In addition, according to the control method of the sensor light according to an embodiment of the present invention, the step (iii) is a step of determining whether to output the first signal for detecting the fluid by operating the first sensing unit, the first signal is output Determining whether the control unit operates, and lighting the lamp from the load control switch unit when the control unit operates.

Further, according to the control method of the sensor light according to the embodiment of the present invention, when the operation delay within the set delay time in step iii), the sensing signal of the fluid is output from the first sensing unit and the second sensing unit Even if it is characterized in that the lamp is kept off.

In addition, according to the control method of the sensor lamp according to an embodiment of the present invention, when the second time of the control unit in step iii) is exceeded, the lamp is turned off.

As described above, according to the sensor lighting control device and the control method using the same according to the embodiments of the present invention, by reducing the malfunction of the sensor by continuously using the sensor for detecting the change in the wavelength of the fluid and the sensor for detecting the sound signal, The effect that the lighting time of the lamp can be adjusted to suit the needs of the fluid is obtained.

In addition, according to the sensor lighting control device and a control method using the same according to the embodiments of the present invention, built-in a variety of functions than the conventional sensor lighting control products, the power control capacity is superior to the maximum 4KW, the overall product size By minimizing the size to 1/2 or less, it is possible to lower the production cost of the product to less than half and supply it to the market at a low price.

In addition, according to the sensor lighting control device and the control method using the same according to the embodiments of the present invention, by adopting the time delay timer circuit it is also possible to prevent the malfunction of the sensor lighting can be generated from the triac and relay.

1 is a block diagram for schematically showing a configuration of a sensor lamp control apparatus according to the prior art.
2 is a block diagram showing the configuration of a sensor lamp control apparatus according to a first embodiment of the present invention.
3 is a circuit diagram illustrating a power supply unit applied to a sensor lamp control apparatus according to a first embodiment of the present invention.
4 is a circuit diagram illustrating a first sensing unit applied to a sensor lamp control apparatus according to a first embodiment of the present invention.
FIG. 5 is a circuit diagram illustrating a first signal output controller and a set time controller applied to a sensor lamp control apparatus according to a first embodiment of the present invention.
6 is a circuit diagram illustrating a load control switch unit applied to a sensor lamp control apparatus according to a first embodiment of the present invention.
7 is a circuit diagram illustrating a second detector and a second signal output controller applied to a sensor lamp control apparatus according to a first embodiment of the present invention.
8 is a flowchart illustrating a control method using a sensor lamp control apparatus according to a first embodiment of the present invention.
9 is a block diagram showing the configuration of a sensor lamp control apparatus according to a second embodiment of the present invention.
10 is a circuit diagram illustrating a power supply unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention.
FIG. 11 is a circuit diagram illustrating a first sensing unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention.
12 is a circuit diagram illustrating a second sensing unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention.
FIG. 13 is a circuit diagram illustrating a load control switch unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention.
14 is a circuit diagram illustrating a control unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention.
15 is a flowchart illustrating a control method using a sensor lamp control apparatus according to a second embodiment of the present invention.

These and other objects and novel features of the present invention will become more apparent from the description of the present specification and the accompanying drawings.

Hereinafter, a sensor lamp control apparatus according to a first embodiment of the present invention will be described in detail with reference to FIGS. 2 to 7. 2 is a block diagram showing the configuration of a sensor lamp control apparatus according to a first embodiment of the present invention. 3 and 4 are circuit diagrams showing a power supply unit and a first sensing unit respectively applied to a sensor lamp control apparatus according to a first embodiment of the present invention, and FIG. 5 is a sensor lamp control apparatus according to a first embodiment of the present invention. 1 is a circuit diagram illustrating a first signal output controller and a set time controller. FIG. 6 is a circuit diagram illustrating a load control switch unit applied to a sensor lamp control apparatus according to a first embodiment of the present invention, and FIG. 7 is a second sensing unit applied to a sensor lamp control apparatus according to a first embodiment of the present invention. And a circuit diagram showing a second signal output controller.

2 to 4, the sensor lamp control apparatus 100 according to the first embodiment of the present invention includes a power supply unit 21 and a first sensing unit 23 for supplying power to the control apparatus. do. The power supply unit 21 includes a connector JP1 and a regulator U6, and serves to supply power to the control circuit of the control device 100 by rectifying AC commercial power into DC power.

For example, the power supply 21 may first rectify 220 V AC power input to the terminals L and N of the connector JP1 into a 24 V DC power supply, so that the load control switch 25 may be described later. Drive the relay K1. The connector JP1 is electrically connected to a light (not shown) that is turned on or off according to the detection of a load, that is, a fluid. In addition, the power supply unit 21 uses a DC power supply for driving the control circuit of the control device 100 by secondary rectifying 220V AC power from the regulator (U6) to 5V DC power.

The first sensing unit 23 includes a first sensor unit 27, a first amplifying unit 29, and a first discriminating unit 31. The first sensor unit 27 detects a first signal emitted from the fluid, for example, an infrared signal. The first sensor unit 27 may use a pyroelectric sensor or a microwave sensor, but is not limited thereto and may use other sensors capable of sensing a fluid. The first amplifier 29 may be configured using operational amplifiers U1A and U1B. The first amplifier 29 amplifies and outputs the first signal detected by the first sensor unit 27 primarily through the operational amplifier U1A. In this case, the first amplifier 29 senses a sensing distance for sensing the fluid by adjusting the size of the variable resistor VR1 electrically connecting the output terminals and the inverting input terminals of the operational amplifiers U1A and U1B, respectively. Can be adjusted. The first signal output from the operational amplifier U1A is secondarily amplified and output through the operational amplifier U1B.

The first discriminating unit 31 receives the first signal output from the operational amplifier U1B and compares the first signal from the comparison circuit including the operational amplifiers U1C and U1D. The first discriminator 31 includes resistors R9, R12, R16, and R19, operational amplifiers U1C and U1D, and diodes D1 and D2 which are used as voltage divider circuits. The first discriminating unit 31 sets the range of the upper voltage and the lower voltage, which are the determination criteria of the voltage levels, from the voltage distribution circuit and the operational amplifiers U1C and U1D. Therefore, the first determination unit 31 may be configured to output the first signal in the form of a pulse through the diodes D1 and D2 when the first signal is out of the range of the upper voltage and the lower voltage. When the fluid is detected by the first sensing unit 23, the first discriminating unit 31 may output a pulse signal having a high state as the first signal.

2, 5 to 7, the first signal output controller 33 includes a NAND gate U2A, diodes D3 and D4, resistors R13, R14, R15, and R18, and a photoconductive device CDS1. ) And a switch SW1. The first discrimination unit 33 controls the signal input to the first input terminal of the NAND gate U2A by using the photoconductive element CDS1 whose resistance varies according to the amount of light to be irradiated. An output signal of the first signal inputted from the input terminal 31 to the second input terminal of the NAND gate U2A is controlled. In this case, the switch SW1 is preferably constituted by a three-stage switch.

When terminals 1 and 2 of the switch SW1 are electrically connected to each other, the voltage applied to the photoconductive element CDS1 is ignored by the resistor R15 connected to the terminal 1 so that 1 of the NAND gate U2A may be ignored. Input voltage 5 V is supplied to input terminal 1. In other words, since a high pulse signal is input to the first input terminal of the NAND gate U2A, when a high pulse signal is input to the second input terminal of the NAND gate U2A, 3 of the NAND gate U2A is input. The output terminal outputs the low pulse signal. Therefore, when the first and second terminals of the switch SW1 are electrically connected, the NAND gate U2A regardless of the change in illuminance, that is, day and night, each time the fluid is sensed by the first sensing unit 23. ) Output pulse signal of low state is output to No. 3 output terminal of) and the lamp is turned on. As a result, the normal mode may be set by electrically connecting terminals 1 and 2 of the switch SW1.

Meanwhile, when terminals 2 and 3 of the switch SW1 are electrically connected to each other, the NAND gate U2A may be formed due to a change in resistance of the photoconductive device CDS1 according to the resistor R13 and illuminance connected to the terminal 3. The pulse signal input to input terminal 1 of is changed. For example, in the daytime, since the periphery of the photoconductive device CDS1 is bright, the resistance of the photoconductive device CDS1 is lowered, and a low pulse signal is input to the first input terminal of the NAND gate U2A. . Therefore, even if the pulse signal of the high state is inputted to the input terminal 2 of the NAND gate U2A, the output signal of the NAND gate U2A does not change.

However, when the periphery of the photoconductive element CDS1 becomes dark, for example, in the evening, the resistance value of the photoconductive element CDS1 becomes high, and a high pulse signal is applied to the first input terminal of the NAND gate U2A. Is entered. Therefore, when the first signal, which is a fluid detection signal, is input to the second input terminal of the NAND gate U2A, the output signal of the NAND gate U2A outputs a pulse signal in a low state to turn on a lamp. As a result, the first night mode may be set by electrically connecting terminals 2 and 3 of the switch SW1.

In contrast, when terminals 2 and 4 of the switch SW1 are electrically connected to each other, the control device 100 sets the resistance value of the resistor R14 connected to terminal 4 to the resistor R13 connected to terminal 3. When the resistance is greater than, the detection signal of the fluid can be output at night, which becomes darker than the evening. Therefore, the second night mode may be set by electrically connecting terminals 2 and 4 of the switch SW1. In conclusion, the control device 100 may be controlled in the normal mode, the first night mode, or the second night mode by electrically connecting terminals 1, 3, or 4 to terminal 2 of the switch SW1. .

Meanwhile, when the fluid is detected, the first signal output controller 33 outputs a pulse signal in a low state, and the pulse signal in the low state is a set time controller 35 electrically connected to the first signal output controller 33. ) Is entered. The set time controller 35 includes a first timer unit 37, a time delay timer unit 39, and a second timer unit 41.

The first timer unit 37 includes a NAND gate U2D, a resistor R23, a variable resistor VR2, a capacitor C16, and a diode D5. The first timer unit 37 receives the pulse signal of the low state output from the first signal output controller 33 through the diode D5 connected in the reverse direction. The NAND gate U2D receives a pulse signal of a high state due to the resistor R23 and the variable resistor VR2 because the input terminals 12 and 13 are short-circuited when the fluid is not detected. Output terminal 11 of the NAND gate U2D outputs a low pulse signal. The NAND gate U2D receives a low pulse signal through input terminals 12 and 13 when a fluid is detected from the first sensing unit 23. Accordingly, the first timer unit 37 receives a high pulse signal from an output terminal 11 of the NAND gate U2D to drive the load control switch unit 25 electrically connected to the first timer unit 37. Output

Meanwhile, the capacitor C16 is charged by the resistor R23 and the variable resistor VR2 electrically connected to the input terminals 12 and 13 of the NAND gate U2D, and the charged capacitor C16 is discharged. The voltage applied to the input terminals 12 and 13 of the NAND gate U2D is increased. Accordingly, signals in a low state are input to terminals 12 and 13 of the NAND gate U2D, and the first timer unit 37 stops driving the load control switch unit 25 to the NAND gate U2D. Output pulse signal of high state to output terminal 11). Therefore, before the capacitor C16 is discharged and the pulse signal of the high state is input to the terminals 12 and 13 of the NAND gate U2D, the pulse signal of the low state is received from the output terminal of the first signal output controller 33. When input to terminals 12 and 13, the lamp can be turned on continuously. In this case, the first timer unit 35 may control the lighting time of the lamp by changing the charging time of the capacitor C16 by adjusting the size of the variable resistor VR2.

On the other hand, when the lamp is turned on, since the resistance value of the photoconductive element CDS1 of the first signal output control unit 33 is lowered, a low pulse signal is input to the first input terminal of the NAND gate U2A. Therefore, in the related art, even if the first sensing unit 23 continuously detects the fluid and outputs the first signal to the first signal output control unit 33, the set time of the first timer unit 37, that is, the first time is increased. After exceeding, there is a problem that the lamp is turned off.

In order to solve the above problems, the control apparatus 100 according to the first embodiment of the present invention uses the NAND gate U2D of the first timer unit 37 through the diode D3 of the first signal output control unit 33. ) The 11th output terminal is electrically connected to the 1st input terminal of the NAND gate U2A of the first signal output controller 33. As a result, the control device 100 outputs the high signal output from the first timer unit 37 when the first signal sensing the fluid in the first sensing unit 23 is input to the first signal output control unit 33. Since the pulse signal in the state is continuously input to the NAND gate U2A input terminal 1 of the first signal output control unit 33, the lamp can be continuously turned on even when the first time of the first timer unit 37 is exceeded. have. The output signal of the first timer unit 37 is input to the load control switch unit 25 electrically connected to the first timer unit 37.

The load control switch 25 includes a triac Q1, which is a semiconductor switch, and a relay K1, which is a mechanical switch, to control power within 2 KW. The triac Q1 is excellent in durability but has a problem in that heat generation characteristics are not excellent when controlling power of 100W or more. In addition, the relay K1 has a problem in that spark may occur at an internal contact point and thus the durability is not excellent. Therefore, the triac Q1 and the relay K1 are preferably connected in parallel with each other in order to solve the problem.

The pulse signal of the high state input to the load control switch 25 is simultaneously connected to the diode D8 connected to the triac Q1 in the forward direction, the diode D10 connected to the relay K1 in the reverse direction, and the resistor R37. Is entered. The pulse signal drives the triac Q1 by charging the capacitor C18 through the diode D8 and supplying a bias voltage to the base of the transistor Q2 through the resistor R32. On the other hand, the pulse signal of the high state does not pass through the diode (D10) connected in the reverse direction, a minute current flows through the resistor (R37) to charge the capacitor (C21). Accordingly, the capacitor C21 is discharged to apply the bias voltage to the base of the transistor Q3 to drive the relay K1 after a predetermined time, for example, 0.5 seconds after the triac Q1 is driven.

When the load power of the control device 100 is controlled only by the relay K1, the control device 100 may malfunction or may not operate due to a spark generated at a contact point inside the relay K1. On the other hand, when controlling the load power of the control device 100 using only the triac (Q1), the control device 100 may malfunction or not operate due to the heat generation characteristics of the triac (Q1). Therefore, the control device 100 of the present invention drives the triac Q1 before the relay K1 and, after a preset time, drives the relay K1 connected in parallel with the triac Q1 to relay K1. Sparks can be prevented from occurring. The triac Q1 has a larger internal resistance than the relay K1 in a driving state. Therefore, since the control device 100 transmits power to the lamp through the relay K1 after the relay K1 is driven, the control apparatus 100 may prevent the triac Q1 from generating heat in advance.

On the other hand, the load control switch unit 25 operates in the reverse order as described above when the pulse signal in the low state is output from the NAND gate U2D after the first time of the first timer unit 37 exceeds. That is, since the current charged in the capacitor C21 is discharged through the diode D10, the transistor K3 is turned off and shut off. The triac Q1 is cut off after a preset time by the capacitor C18, for example 0.5 seconds after the relay K1 is cut off. As a result, the lamp is turned off. Unlike the prior art adopting the microcomputer, the control device 100 controls the lighting of the lighting lamp with the triac Q1 and the relay K1, thereby lowering the manufacturing cost. In addition, since the control device 100 can eliminate the process of inputting the control program to the microcomputer, the manufacturing process of the control device 100 can be reduced.

The time delay timer unit 39 includes a NAND gate U5A, a diode D7, a resistor R35, and a capacitor C20. The input terminal 1 of the NAND gate U5A is electrically connected to the output terminal 11 of the NAND gate U2D of the first timer unit 37, and the input terminal 2 of the NAND gate U5A is NAND gate. (U2D) It is electrically connected to input terminal 13. In addition, the third output terminal of the NAND gate U5A is electrically connected to the first input terminal of the NAND gate U2A through the diode D4 of the first signal output control unit 33 connected in the reverse direction.

When the fluid is not detected by the first sensing unit 23, the time delay timer unit 39 inputs a low pulse signal to the first input terminal of the NAND gate U5A and a high input terminal to the second input terminal. Since the pulse signal of the state is input, the pulse signal of the high state is output to the third output terminal of the NAND gate U5A. The high output signal does not affect the output of the first signal output controller 33 due to the diode D4 of the first signal output controller 33 connected in the reverse direction to the first input terminal of the NAND gate U2A. Do not.

On the other hand, when the first signal, which is a fluid detection signal, is output from the first signal output controller 33, the first input terminal of the NAND gate U5A receives a pulse signal having a high state, and the second input terminal. A pulse signal in a low state is input to the output signal, and a high state output signal is output to an output terminal 3 of the NAND gate U5A. Therefore, even when a high pulse signal is output from the first signal output control unit 33, when the first timer unit 37 operates, the output signal of the high state is applied to the first input terminal of the NAND gate U2A. The diode D4 of the first signal output controller 33 connected in the reverse direction does not affect the output of the first signal output controller 33.

However, when the first time of the first timer unit 37 is exceeded, the NAND gate U5A input terminal 1 of the time delay timer unit 39 is in a high state due to the current charged in the capacitor C20. The input pulse signal of the NAND gate (U5A) terminal 2 receives a high pulse signal. The low pulse signal output from the third output terminal of the NAND gate U5A is input to the first NAND gate U2A terminal 1 of the first signal output controller 33 through the diode D4 connected in the reverse direction.

Accordingly, the NAND gate U2A of the first signal output controller 33 is electrically connected to the first signal output controller 33 through the first detector 23 and the second signal output controller 43. Even if the fluid detection signal is input to the second input terminal from the detection unit 45, the pulse signal in a high state is output. In other words, the first signal output control unit 33 does not operate even when the fluid is detected from the first sensing unit 23 and the second sensing unit 45. As a result, the time delay timer 39 prevents malfunctions of the first sensing unit 23 and the second sensing unit 45 which may occur from power supply noise when the load control switch unit 25 is turned off. Can be.

On the other hand, the time delay timer 39 changes the output signal of the NAND gate U5A to a high state after a predetermined time, for example, one second, when all the charging currents of the capacitor C20 are discharged. Therefore, the output signal of the time delay timer 39 is not input to the first signal output controller 33 due to the diode D4 connected in the reverse direction.

The second sensing unit 45 is electrically connected to the first signal output control unit 33 through the second signal output control unit 43. The second sensing unit 45 includes a second sensor unit 47, a second amplifying unit 49, and a second discriminating unit 51. The second sensor unit 47 detects the second signal generated from the fluid only for a predetermined time when the fluid is out of the sensing distance of the first sensor unit 27. Preferably, the second signal is an audio signal generated from the fluid. In other words, the second sensor unit 47 preferably includes a microphone MK1.

The second amplifier 49 may be configured using operational amplifiers U3A and U3B. The second amplifier 49 amplifies and outputs the second signal detected by the second sensor unit 47 primarily through the operational amplifier U3A. In this case, the second amplifier 49 adjusts the size of the variable resistor VR3 electrically connecting the output terminals and the inverting input terminals of the operational amplifiers U3A and U3B to determine a sensing distance for detecting the fluid. I can adjust it. The second signal output from the operational amplifier U3A is secondarily amplified and output through the operational amplifier U3B.

The second discriminating unit 51 receives the second signal output from the operational amplifier U3B and compares it from a comparison circuit including the operational amplifiers U1C and U1D. The second discriminating unit 51 includes resistors R27, R31, R33, and R36, operational amplifiers U3C and U3D, and diodes D6 and D9 which are used as voltage divider circuits. The second discriminating unit 51 sets the range of the upper voltage and the lower voltage, which are the determination criteria of the voltage levels, from the voltage distribution circuit and the operational amplifiers U3C and U3D. Therefore, the second discriminating unit 51 may be configured to output the second signal in the form of a pulse through the diodes D6 and D9 when the second signal is out of the range of the upper voltage and the lower voltage. When the fluid is sensed by the second sensing unit 45, the second discriminating unit 51 outputs a high pulse signal to the second signal output control unit 43. The second signal output controller 43 receives an output signal of each of the second detector 45 and the second timer 41 and outputs the output signal to the first signal output controller 33.

The second signal output controller 43 includes NAND gates U2B and U2C and a diode D2. The output terminal of the NAND gate U2B is electrically connected to an input terminal of the NAND gate U2A of the first signal output controller 33 through a diode D2 connected in the forward direction. The input terminal 8 of the NAND gate U2C is electrically connected to the output terminal of the second timer unit 41, and the input terminal 9 of the NAND gate U2C is forward from the second discriminating unit 51. It is electrically connected to the output terminal of the NAND gate U3C through the diode D6 connected to the gate.

In addition, an input terminal 9 of the NAND gate U2C is electrically connected to an output terminal of the NAND gate U3D d through a diode D9 connected in a forward direction from the second discriminating unit 51. The output terminal 10 of the NAND gate U2C is electrically connected to the input terminals 5 and 6 of the NAND gate U2B. That is, input terminals 5 and 6 of the NAND gate U2B are connected to each other in a short circuit state.

The second timer part 41 includes NAND gates U5B and U5C, a resistor R39, a capacitor C22, and a diode D11. The output terminal of the NAND gate U5B is electrically connected to an input terminal 8 of the NAND gate U2C of the second signal output controller 43, and the output terminal of the NAND gate U5C is 5 of the NAND gate U5B. Electrically connected to Inputs # 6 and # 6. Input terminal 8 of the NAND gate U5C is a NAND gate U2D output terminal and a time delay of the load control switch 25, the diode D3, and the first timer 37 through the dial D11. It is electrically connected to the timer unit 39. In addition, an input terminal 9 of the NAND gate U5C is connected to an input terminal 13 of the NAND gate U2D of the first timer unit 37 and an input terminal 1 of the NAND gate U5A of the time delay timer unit 39. It is electrically connected.

When the fluid is not detected by the first sensing unit 23, a pulse signal of a low state is input to the NAND gate U5C 8 input terminal of the second timer 41, and the 9th input terminal. The pulse signal in the high state is input. Accordingly, the NAND gate U2B output terminal of the second timer unit 41 outputs a high pulse signal to the NAND gate U2C input terminal 8 of the second signal output control unit 43.

On the other hand, when the fluid is detected in the first sensing unit 23 and the first timer unit 37 operates, the current discharged from the capacitor C22 electrically connected to the input terminal 8 of the NAND gate U5C. Therefore, a high pulse signal is input to the eighth input terminal, and a low pulse signal is input to the nineth input terminal so that the output terminal of the NAND gate U5B receives a low pulse signal as a second signal output control unit ( 43). When the first time of the first timer unit 37 is exceeded, the lamp is turned off and a pulse signal of a high state is applied to the NAND gate U5C input terminal 9 of the second timer unit 41. . In addition, the second timer unit 41 applies a pulse signal of a high state to the input terminal 8 of the NAND gate U5C for a second time when all the charging currents of the capacitor C22 are discharged, for example, 6 seconds. As a result, the second signal output controller 43 is maintained in an operable state.

Meanwhile, the second signal output controller 43 receives the output signal of the second timer unit 41 and the second signal of the second detector 45 and receives the first signal output controller through the diode D2. 33) to output a pulse signal. Therefore, the control device 100 inputs the second signal of the fluid detected from the second sensing unit 45 to the first signal output control unit 33 to light the lamp.

As a result, the control device 100 of the present invention operates the load control switch unit 25 from the first signal of the first sensing unit 23 to turn on a lamp and the first time of the first timer unit 37. If the time is exceeded, turn off the lamp. In addition, the control device 100 operates the second timer unit 41 after the load control switch unit 25 is turned off so that the first signal output control unit 33 receives the second signal generated from the fluid for a second time. It is possible to continue lighting the lamp by applying a. In other words, the control device 100 controls the power applied to the lamp by sensing the first signal generated from the fluid by using the first sensing unit 23, and the fluid of the first sensing unit 23. When the lamp is turned off beyond the detection range, the lamp is controlled by detecting the second signal generated from the fluid using the second detector 45 for a second time.

Reference numerals 201 to 205 not described with reference to FIGS. 3 to 7 mean that the same reference numerals are electrically connected to each other in each of the drawings. For example, reference numerals 201 and 202 of FIG. 3 are electrically connected to the same reference numerals of FIG. 6.

Next, a control method using a sensor lamp control apparatus according to a first embodiment of the present invention will be described with reference to FIGS. 2 and 8. 8 is a flowchart illustrating a control method using a sensor lamp control apparatus according to a first embodiment of the present invention.

2 and 8, the method of controlling a sensor lamp according to the first embodiment of the present invention includes operating the first sensing unit 23 to detect a fluid (S81). The first detection unit 23 preferably detects a fluid using an infrared sensor or a microwave sensor. The first detection unit 23 outputs a first signal when detecting the fluid (S82). The first signal is input to a set time controller 35 including a first timer unit 37, a time delay timer unit 39, and a second timer unit 41. The set time control unit 35 operates the load control switch unit 25 from the pulse signal of the high state output from the first timer unit 37 to turn on a lamp (S84). In this case, the lamp maintains an unlit state when a low pulse signal is output from the setting time controller 35 (S85).

After the step S85, it is determined whether the first signal which is the fluid detection signal is continuously output from the first detection unit 23 (S86). In the step S86, when the fluid is continuously detected from the first sensing unit 23, the lamp is kept on. In contrast, when the fluid is out of the sensing distance of the first sensing unit 23, it is determined whether the first time, which is the set time of the first timer unit 37, has been exceeded (S87). In step S87, the lamp is kept lit when within the first time. In contrast, the load control switch unit 25 turns off the lamp when the first time of the first timer unit 37 exceeds (S88).

After the step S88, it is determined whether or not the set time of the time delay timer unit 39 has been exceeded. In this case, when the time delay timer 39 is within the set time, the load control switch 25 may be used even if a sensing signal of the fluid is output from the first sensing unit 23 and the second sensing unit 45. Keep the lights off. As a result, the time delay timer 39 prevents malfunctions of the first sensing unit 23 and the second sensing unit 45 which may occur from power supply noise when the load control switch unit 25 is turned off. Can be.

In step S88, when the setting time of the time delay timer unit 39 is exceeded, it is determined whether or not the second time which is the setting time of the second timer unit 41 is exceeded (S89). In the step S89, if the second time is exceeded, the lamp is kept off. In contrast, when it is within the second time, it is determined whether the second signal, which is a detection signal of the fluid, is output from the second detection unit 45 (S91). In the step S91, when the second signal is output, the load control switch 25 is operated to turn on the lamp again (S92). In this case, when the second signal is continuously output, the lamp is kept in a lit state, and when the fluid is out of the detection range of the second detector 45, the lamp is turned off after the second time has elapsed. .

Next, a sensor lamp control apparatus according to a second embodiment of the present invention will be described in detail with reference to FIGS. 9 to 14. 9 is a block diagram showing the configuration of a sensor lamp control apparatus according to a second embodiment of the present invention, Figure 10 is a circuit diagram showing a power supply applied to the sensor lamp control apparatus according to a second embodiment of the present invention. FIG. 11 is a circuit diagram illustrating a first sensing unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention. 12 is a circuit diagram illustrating a second sensing unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention, and FIG. 13 is a load control switch unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention. 14 is a circuit diagram illustrating a control unit applied to a sensor lamp control apparatus according to a second embodiment of the present invention.

9 to 14, the sensor lamp control apparatus 200 according to the second embodiment of the present invention is the power supply unit 121 and the first sensing unit 123, the power supply for supplying power to the control device It comprises a two sensing unit 125, the load control switch unit 127 and the control unit 129. The first sensing unit 123 includes a first sensor unit 131, a first amplifying unit 133, and a first discriminating unit 135, and the second sensing unit 125 includes a second sensor unit ( 137, a second amplifier 139, and a second discriminator 141. Although the power supply unit 121, the first sensing unit 123, and the load control switch unit 127 have some differences in some circuit configurations, detailed descriptions thereof will be omitted because they perform the same functions as those of the first embodiment. .

Meanwhile, the controller 129 serves as the first signal output controller 33, the set time controller 35, and the second signal output controller 43 described in the first embodiment. The control unit 129 is preferably configured as a microcomputer. Therefore, the controller 129 may serve as the first signal output controller 129, the second signal output controller 129, and the set time controller 129 by a preset program. The control unit 129 controls the load control switch unit 127 when the first signal is input from the first sensing unit 123 to turn on a lamp for a first time, and when the first time is exceeded. Turn off the lights.

In addition, the controller 129 turns off the lamp even if a detection signal of the fluid is output from the first detector 123 and the second detector 125 during the operation delay setting time after the lamp is turned on for the first time. Keep it in a state. Therefore, the control unit 129 may prevent the first detection unit 123 and the second detection unit 125 from malfunctioning when the load control switch unit 127 is turned off.

In addition, the control unit 129 exceeds the second time, which means the time that the load control switch unit 127 can operate from the second signal of the second sensing unit 125 after the operation delay setting time is exceeded. Judge. That is, the control unit 129 controls the load control switch unit 127 to light the lamp when the second detection unit 125 detects the second signal from the fluid within the second time. In contrast, the controller 129 does not output the second signal, which is a detection signal of the fluid, from the second detection unit 125 within the second time, or when the fluid is outside the detection range of the second detection unit 125. Turn off the lamp after the second time has passed. Therefore, the control device for the sensor lamp according to the second embodiment of the present invention can reduce the size of the control device by adopting a microcomputer control unit equipped with a control program, and can easily repair a failure of the control device or a program error. have.

Meanwhile, reference numerals 301 to 206 not described with reference to FIGS. 10 to 14 mean that the same reference numerals are electrically connected to each other in each of the drawings. For example, reference numerals 301 and 302 of FIG. 10 are electrically connected to the same reference numerals of FIG. 13.

Next, a control method using a sensor lamp control apparatus according to a second embodiment of the present invention will be described with reference to FIGS. 9 and 15. 15 is a flowchart illustrating a control method using a sensor lamp control apparatus according to a second embodiment of the present invention.

9 and 15, the method of controlling a sensor lamp according to the second embodiment of the present invention includes operating the first sensing unit 123 to detect a fluid (S181). The first detection unit 123 preferably detects a fluid by using an infrared sensor or a microwave sensor. The first detection unit 123 outputs a first signal when detecting a fluid (S182). The first signal is input to the controller 129 to operate the load control switch unit 127 under the control of the controller 129 to turn on the lamp (S183, S184). In this case, the lamp maintains an unlit state when a low pulse signal is output from the controller 129 (S185).

After the step S185, it is determined whether the first signal which is the fluid detection signal is continuously output from the first detection unit 123 (S186). In the step S186, when the fluid is continuously detected from the first sensing unit 123, the lamp is kept lit. In contrast, when the fluid is out of the sensing distance of the first sensing unit 123, it is determined whether the first time, which is the set time of the control unit 129, is exceeded (S187). In step S187, the lamp maintains a lighting state when it is within the first time. In contrast, the load control switch 127 turns off the lamp when the first time of the controller 129 is exceeded (S188).

After the step S188, it is determined whether the operation delay setting time of the controller 129 has been exceeded. The operation delay setting time refers to a time for maintaining the lamp in an unlit state even when a detection signal of the fluid is output from the first sensing unit 123 and the second sensing unit 125 after the first time is exceeded. Accordingly, when the load control switch 127 is within the operation delay setting time, the load control switch 127 turns off the lamp even when a sensing signal of the fluid is output from the first sensing unit 123 and the second sensing unit 125. Keep it. As a result, the control unit 129 may prevent the first detection unit 123 and the second detection unit 125 from malfunctioning when the load control switch unit 127 is turned off.

In operation S188, when the operation delay setting time of the controller 129 is exceeded, it is determined whether the second time of the controller 129 is exceeded (S189). The second time means a time at which the load control switch 127 can operate from the second signal of the second sensing unit 125 after the operation delay setting time is exceeded. That is, the control unit 129 controls the load control switch unit 127 to light the lamp when the second detection unit 125 detects the second signal from the fluid within the second time.

In the step S189, if the second time is exceeded, the lamp is kept off. In contrast, when it is within the second time, it is determined whether the second signal, which is a detection signal of the fluid, is output from the second detection unit 125 (S191). When the second signal is output in step S191, the load control switch unit 127 operates to turn on the lamp again (S192). In this case, when the second signal is continuously output, the lamp remains in a lit state, and when the fluid is outside the detection range of the second detector 125, the lamp is turned off after the second time is exceeded. .

Although the invention made by the present inventors has been described in detail according to the above embodiments, the present invention is not limited to the above embodiments and can be variously modified without departing from the gist thereof.

21, 121: power supply unit 23, 123: first detection unit
25, 127: load control switch unit 27, 131: first sensor unit
29, 133: first amplifier 31, 135: first judgment
33: first signal output controller 35: set time controller
37: first timer unit 39: time delay timer unit
41: second timer unit 43: second signal output control unit
45, 125: second detection unit 47, 137: second sensor unit
49, 139: second amplifier 51, 141: second discrimination
129: control unit

Claims (13)

A first sensing unit for outputting a first signal generated from the fluid;
A first signal output control unit including a NAND gate, a diode, a resistor, a photoconductive device, and a switch, and receiving the first signal and outputting a signal according to a change in illuminance outside the first sensing unit;
A set time controller operating according to an output signal of the first signal output controller;
A load control switch unit configured to control an on / off state of a lamp in response to an output signal of the set time controller;
A second sensing unit which outputs a second signal generated from the fluid when the lamp in an on state is turned off according to the first signal of the first sensing unit; And
And a second signal output control unit having a NAND gate and a diode and controlling the signal output to the first signal output control unit by receiving the second signal.
The set time control unit
The first timer unit includes a NAND gate, a resistor, a variable resistor, a capacitor, and a diode, and outputs a signal input from the first signal output controller to the first signal output controller and the load control switch for a first time. ;
And a NAND gate, a resistor, a capacitor, and a diode, and control a signal input to the second signal output control unit for a second time according to the input / output signal of the first timer unit, and the first time of the first timer unit. A second timer unit controlling the operation of the second signal output controller when the lamp is turned off in excess of the above; And
And a NAND gate, a diode, a resistor, and a capacitor, and controlling the signal input to the first signal output controller for a set delay time when the load control switch unit is switched from an on state to an off state. Sensor lighting control device comprising a time delay timer that can prevent a malfunction. delete The method of claim 1, wherein the first detection unit
A first sensor unit detecting a first signal generated from the fluid;
A first amplifier for amplifying the first signal; And
And a first discrimination unit configured to determine and output a signal input to the first signal output controller by controlling and outputting the amplified first signal. The method of claim 1, wherein the first signal output control unit
It operates in the normal mode irrespective of the change in the illuminance outside the first sensing unit or in the first night mode and the second night mode in accordance with the change in the external illuminance to adjust the signal input to the set time controller. Sensor lighting controller. The method of claim 1,
And the first sensing unit senses a change in wavelength generated from the fluid, and the second sensing unit senses a sound signal generated from the fluid. The method of claim 1, wherein the second detection unit
A second sensor unit sensing a second signal generated from the fluid;
A second amplifier for amplifying the second signal; And
And a second discrimination unit configured to determine and output a signal input to the second signal output controller by controlling and outputting the amplified second signal. The method of claim 1,
The load control switch unit includes a triac and a relay,
The triac and the relay is a control lamp sensor, characterized in that the on / off operation time is different. The method of claim 7, wherein
The triac is operated first when the load control switch is turned on, and the relay is operated first when the load control switch is turned off. delete delete delete delete delete

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