KR200346592Y1 - Sensor light - Google Patents

Abstract

The present invention relates to a sensor lamp that lights up in response to an approach of a human body immediately and lights up continuously when the human body stays within a detection range of the sensor after the lighting.

According to the present invention, the sensor 52 for detecting the approach of the human body is installed so as to expose the sensor to turn on the lamp 54 when the human body approaches, the sensor 52 is connected to the sensor 52 of the human body An amplifying unit 56 that amplifies and outputs an approach when detected, and a first comparing unit connected to the amplifying unit 56 to generate an output signal when the output of the amplifying unit 56 is a positive voltage of a predetermined reference voltage or more. A second comparator 60 connected to the amplification part 56 to generate an output signal when the output of the amplification part 56 is a negative voltage below a predetermined reference voltage; A lighting time setting unit 62 connected to the second and second comparing units 60 and outputting a lighting signal of the lamp 54 for a predetermined time when an output signal is generated in any one of the comparing units 58 and 60. And the lamp 54 connected to the lighting time setting unit 62 according to the lighting signal of the lighting time setting unit 62. Provided is a sensor lamp comprising a lamp driver 64 for driving lighting.

Description

Sensor light

The present invention relates to a sensor, and more particularly, to a sensor, such that the sensor is turned on immediately in response to the approach of the human body, and continuously detects the movement of the human body after being turned on and maintains the lighting state if there is a movement of the human body. .

In general, the sensor is installed in the apartment or other indoor porch or balcony, a device that automatically turns on the lamp by detecting the access of the person entering the entrance or balcony. 1 is a perspective view illustrating an example of a conventional sensor, and FIG. 2 is a block diagram schematically showing a configuration of a conventional sensor. Referring to this, the conventional sensor is an infrared sensor or a side of a housing 10 installed on a ceiling. A sensor 12 for detecting a human body approach, such as a heat sensor, is installed to expose the amplification unit 14 for amplifying a signal detected by the sensor 12 inside the housing 10, and a reference voltage and an amplification unit. Comparing unit 18 for comparing the output of (14) to output the lamp 16 lighting signal, the lighting time setting unit 20 for determining the lighting time of the lamp 16, and driving the lamp 16 The lamp driver 22 is designed and configured.

However, although the signal detected by the sensor 12 is a minute current and variably changes to a plus level or a minus level in some cases, the comparison unit 18 such as a conventional sensor simply provides a detection signal of the sensor 12. It is configured to react immediately only when the reference voltage is above a predetermined value, that is, only when the detection signal of the sensor 12 is at the plus level. Therefore, when the signal at the moment of detecting the approach of the human body in the sensor 12 stays at a negative level, no output is generated in the comparator 18, and thus the human body approaches the detection range of the sensor 12. In many cases, the sensor lights are turned on too late.

In addition, the lighting time setting unit 20 is configured to turn on the lamp 16 only for a predetermined time by a timer or the like when a signal of the human body is detected by the sensor 12 and the signal is transmitted. However, when a person stays within the detection range of the sensor 12, even though the detection signal is continuously output by the sensor 12, the timer automatically turns off the lamp 16 after a predetermined time, so that the user It will cause inconvenience. Afterwards, when a person stays under the sensor lamp for a long time, the lamp 16 repeatedly turns on and off, so that it is difficult to perform simple work under the sensor lamp, and unnecessary power is consumed.

The present invention is to solve the above problems, the object of the present invention is to respond to the immediate response to the human body within the detection range of the sensor to be lit immediately, if the movement of the human body to continue to detect the movement of the human body after lighting It is to provide a sensor light to be kept lit.

1 is a perspective view showing an example of a conventional sensor, etc.

2 is a block diagram conceptually showing a circuit configuration of a conventional sensor or the like.

3 is a block diagram conceptually showing a circuit configuration of a sensor according to the present invention.

4 is a circuit diagram showing an example of a sensor and the like according to the present invention

5 is a perspective view showing an embodiment of a sensor, etc. according to the present invention

<Description of the symbols for the main parts of the drawings>

50. Housing 52. Sensor

54. Lamp 56. Amplifier

58. First comparator 60. Second comparator

62. Lighting time setting part 64. Lamp driving part

66. Comparator

According to the present invention, the sensor 52 is installed so that the sensor 52 for detecting the approach of the human body is exposed to one side of the housing 50 installed on the ceiling, the sensor 52 to turn on the lamp 54 when the human body approaches, the sensor 52 When connected to the sensor 52 detects the approach of the human body amplification unit 56 for amplifying and outputting, and the output of the amplification unit 56 is connected to the amplification unit 56 is a positive voltage of a predetermined reference voltage or more A first comparator 58 for generating an output signal and a second comparator connected to the amplifying part 56 to generate an output signal when the output of the amplifying part 56 is a negative voltage below a predetermined reference voltage. 60 is connected to the first comparator 58 and the second comparator 60, and when one of the comparators 58 and 60 generates an output signal, a lighting signal of the lamp 54 for a predetermined time. Is connected to the lighting time setting section 62 and the lighting time setting section 62 to output the lighting time setting. And a lamp driver 64 which turns on and drives the lamp 54 according to the lighting signal of the government 62, wherein the first comparator 58 immediately turns on when the detection signal of the sensor 52 is at the plus level. The second comparator 60 is configured to react immediately when the detection signal of the sensor 52 is at a negative level, so that the sensor can be turned on in response to the human body's approach. Is provided.

According to another feature of the present invention, the lighting time setting unit 62 includes a delay circuit unit 63 for delaying the output signal of the first comparator 58 or the second comparator 60 for a predetermined time. The delay circuit unit 63 is connected to the output terminal of the first comparator 58 or the second comparator 60 to determine the lighting time of the lamp 54, the capacitor C8, the predetermined reference voltage and the capacitor C8. Comparator 66 for outputting a lamp 54 lighting signal by comparing the outputs of the lamps, and if the output signal is applied from the comparators 58 and 60 even after the lamp 54 is turned on, Charging is performed to provide a sensor lamp, characterized in that the lamp 54 is continuously lit while the human body stays within the detection range of the sensor 52.

Hereinafter, described with reference to the accompanying drawings, preferred embodiments of the present invention is as follows. 3 is a block diagram conceptually showing a circuit configuration of a sensor and the like according to the present invention, FIG. 4 is a circuit diagram showing an example of a sensor and the like according to the present invention, and FIG. 5 is an embodiment of a sensor and the like according to the present invention. It is a perspective view shown.

For reference, the sensor may include a sensor 52 for detecting the approach of a human body, an amplifying unit 56 for amplifying a detection signal of the sensor 52, and an output signal of the amplifying unit 56 having a reference voltage or more. A first comparator 58 for generating an output signal at a positive level, a second comparator 60 for generating an output signal when the output signal of the amplifier 56 is at a negative level below a reference voltage; According to the outputs of the comparators 58 and 60, a lighting time setting unit 62 outputs a lighting signal of the lamp 54 for a predetermined time, and a lamp 54 is applied by receiving a signal from the lighting time setting unit 62. And a lamp driver 64 for driving lighting.

Preferably, the lighting time setting unit 62 includes a comparator 66 for comparing the reference voltage with the output signal from the first comparator 58 or the second comparator 60, and thus the lamp 54 It is configured to newly set the lighting time when an output signal is generated from any one of the comparators 58 and 60 in the isochronous state.

3 and 4 is a block diagram and a circuit diagram according to an embodiment of the sensor of the present invention, with reference to this will be described in more detail with respect to the circuit configuration of the present invention.

First, the sensor 52 is an infrared sensor or a heat sensor, and is installed to be exposed to the outside of the housing 50 in which the present invention is accommodated to detect that the human body approaches the detection range. When the human body approaches the detection range of the sensor 52, the sensor 52 outputs a fine current. The output signal from the sensing unit 53 including the sensor 52, which is composed of resistors and condensers, is transmitted to the amplifying unit 56, and the amplifying unit 56 amplifies the detection signal of the sensor 52. In this embodiment, the amplifier 56 is composed of two comparators (U2A, U2B), the detection signal of the sensor 52 is amplified and output in two stages from the two comparators (U2A, U2B). The output of the amplifier 56 is transmitted to the first comparator 58 and the second comparator 60. First, the first comparator 58 includes a comparator U2C in which the output of the amplifier 56 is a non-inverting terminal and a reference voltage is input to the inverting terminal, and the output of the amplifier 56 is greater than or equal to the reference voltage. At this plus level, an output signal is generated. In addition, corresponding to this, the second comparator 60 includes a comparator U2D in which an output of the amplifier 56 is an inverting terminal and a reference voltage is input to a non-inverting terminal, and an output of the amplifier 56 is output. An output signal is generated when the negative level is below this reference voltage. The reference voltage of each of the comparators U2C and U2D may be switched by a plurality of resistors having different resistance values, thereby changing the reference voltage level, and receiving each of the comparators 58 and 60 as the reference voltage level changes. The sensitivity is adjusted. Sensitivity adjustment switch 68 (SW1, SW4) for varying the reference voltage level is mounted so as to be exposed to one side outside the housing 50, as shown in Figure 5, it is protected by a separate cover (70).

The outputs of the first comparator 58 and the second comparator 60 are transmitted to the lighting time setting unit 62. In this case, diodes D5 and D6 for preventing reverse bias are connected to the output terminals of the two comparators 58 and 60, respectively. The lighting time setting part 62 includes a delay circuit part 63 for delaying the output signal of the first comparator 58 or the second comparator 60 for a predetermined time. The delay circuit unit 63 is connected to the output terminal of the first comparator 58 or the second comparator 60 to determine the lighting time of the lamp 54, the capacitor C8, the predetermined reference voltage and the capacitor C8. And a comparator 66 for outputting a lamp 54 lighting signal by comparing the output of the &quot; First, when an output signal is generated from any one of the two comparison units 58 and 60, the charging of the capacitor C8 starts and the lighting of the lamp 54 is maintained until the capacitor C8 completes the discharge. When the output signal is applied from the comparators 58 and 60 even after the lamp 54 is turned on, the capacitor C8 is continuously charged, so that the lamp 54 stays within the detection range of the sensor 52. Lights up continuously. In the lighting time setting section 62, a lighting time setting switch 72 (SW3) is provided. The lighting time setting switch 72 serves to adjust the lighting time of the lamp 54 by switching a plurality of resistors having different resistance values to adjust the charge / discharge cycle of the capacitor C8. The lighting time setting switch 72, like the sensitivity control switch 68, is mounted to be exposed to one side of the housing 50 outside.

Meanwhile, as shown in the circuit diagram of FIG. 4, the output of the lighting time setting unit 62 may be transmitted to the lamp driver 64 via the day / night selection switching unit 74. This day and night switching unit 74 is for selectively blocking the operation of the lamp driver 64 during the day, or to adjust the brightness of the lamp 54 according to the time, the comparator 66 of the lighting time setting unit 62 ), The output voltage is dropped by the distribution resistance value determined by the day and night selection switch 76 (SW2), and is transmitted to the input terminal of the comparator U3A of the day and night switching unit 74 to select day and night. The output of the day / night selection switching unit 74 is transmitted to the lamp driver 64 through the phototransistor PT1. When the phototransistor PT1 is triggered, the switching transistor Q3 is turned on to relay the lamp driver 64. RY1 is activated, and the lamp 54 is turned on accordingly. Meanwhile, reference numeral 78 in the drawing shows a rectifier circuit portion 78 for converting an AC commercial power into a constant voltage DC power supply and supplying the circuit, and the detailed description thereof will be omitted because it is the same as the rectifier circuit used in a conventional circuit.

The sensor or the like of the present invention as described above immediately reacts when the detection signal of the sensor 52 in the first comparator 58 is at a plus level higher than or equal to the reference voltage, and the sensor 52 of the second comparator 60 It is configured to react immediately when the detection signal is at a negative level equal to or greater than the reference voltage. When the human body approaches the detection range of the sensor 52, the lamp 54 is immediately turned on in response thereto. Therefore, it is possible to solve the problem that the conventional sensor light is inconvenient to use after the human body is turned on late. In addition, the lighting time setting unit 62 continuously responds to the output signal generated from the first comparator 58 or the second comparator 60 to detect the sensor 52 even after the lamp 54 is turned on. If the human body stays within the range, there is an advantage that the lighting of the lamp 54 is maintained.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

As described above, according to the present invention, irrespective of whether the detection signal of the sensor is a positive level or a negative level, when the human body approaches the detection range of the sensor, the human body is within the detection range of the sensor. It is possible to provide a sensor lamp in which the lighting time is continuously reset so that the lighting is maintained.

Claims (2)

The sensor 52 is installed so that the sensor 52 for detecting the approach of the human body is exposed to one side of the housing 50 to be installed on the ceiling, so that the lamp 54 is turned on when the human body approaches, the sensor 52 is connected to the sensor 52 52, an amplification unit 56 for amplifying and outputting the human body's approach and an output signal generated when the output of the amplification unit 56 is connected to the amplification unit 56 is a positive voltage of a predetermined reference voltage or more. A first comparator 58 and a second comparator 60 connected to the amplification part 56 to generate an output signal when the output of the amplification part 56 is a negative voltage below a predetermined reference voltage; The lighting time connected to the first comparator 58 and the second comparator 60 and outputting a lighting signal of the lamp 54 for a predetermined time when an output signal is generated in any one of the comparators 58 and 60. Connected to the setting section 62 and the lighting time setting section 62, the lighting scene of the lighting time setting section 62 And a lamp driver 64 for driving and driving the lamp 54 according to the present invention, wherein the first comparator 58 reacts immediately when the detection signal of the sensor 52 is at a plus level, and the second comparison is performed. The unit 60 is configured to react immediately when the detection signal of the sensor 52 is at a negative level, the sensor lamp, characterized in that it can be turned on immediately in response to the human approach. The method of claim 1, wherein the lighting time setting section 62 includes a delay circuit section 63 for delaying the output signal of the first comparator 58 or the second comparator 60 for a predetermined time, the delay circuit section The capacitor 63 is connected to the output terminal of the first comparator 58 or the second comparator 60 to determine the lighting time of the lamp 54, the reference voltage of the predetermined value and the capacitor C8 Comparator 66 for comparing the output and output the lamp 54 lighting signal, and is continuously charged in the capacitor (C8) when the output signal is applied from the comparators 58, 60 even after the lamp 54 is turned on It is made, the sensor lamp, characterized in that the lamp 54 is continuously kept lit while the human body stays within the detection range of the sensor 52.