KR20080006736A - Lighting apparatus - Google Patents

Abstract

A lighting apparatus is provided to reduce power consumption of the lighting apparatus by turning on/off a lamp by detecting a movement of a human body using an embedded sensor. A lighting apparatus includes a lamp(200) and a cover(100). An MMSM(300) is embedded in the cover. The MMSM(Microwave Motion-Sensor Module) controls on/off states of the lamp by detecting an existence of a human body using an electromagnetic signal within a microwave band. The lamp is an incandescent lamp or a halogen lamp. The lamp is directly powered by the MMSM. An electric ballast for controlling the fluorescent lamp according to an output from the MMSM is arranged between the MMSM and a fluorescent lamp.

Description

Lighting apparatus

1 is a view showing the external structure of the lighting apparatus according to an embodiment of the present invention,

Figure 2 is a block diagram showing the configuration of a microwave operation sensor module built in the lighting apparatus of the present invention,

3 is a circuit diagram showing the configuration of the microwave operation sensor module built in the lighting apparatus of the present invention;

Figure 4 is a circuit diagram showing one embodiment of a microwave sensor applied to the microwave operation sensor module of the present invention.

The present invention relates to a lighting device, a microwave operation sensor module (Microwave Motion-Sensor Module) is built-in lighting that can control the on / off of the light by detecting the movement of the human body without exposing the sensor to the outside of the light Relates to a device.

Lighting device automatically adjusts lighting on / off according to the taste of modern man who pursues convenience of lighting control in the way that user manually controls the presence or absence of power supply or by using sensor in the energy saving dimension. Has evolved in a controlled manner.

In the conventional automatic lighting apparatus using an infrared sensor module mounted inside the lighting device, the sensor unit of the sensor module in the glass or acrylic cover constituting the exterior of the lighting device to detect the infrared rays generated from the human body In general, the sensor part was exposed to the outside by drilling a position corresponding to the part.

However, when the cover is perforated to configure the lighting device that is automatically turned on or off according to the presence or movement of the human body, the aesthetics of the lighting device are not impaired, and the installation of the lighting device of the specific design is impossible. There was a problem that acts as a limiting factor in the design design.

In addition, functions such as high power saving effect and long detection range have been commonly requested for automatic lighting devices using sensors.

The present invention has been made to solve the above problems, it is built as a microwave sensor module (Microwave Motion-Sensor Module) as a sensor module to monitor the movement of the human body, etc. without exposing the sensor to the outside of the cover of the lighting device It is an object of the present invention to provide a lighting device that can detect and control the lighting on / off.

In addition, another object of the present invention is to provide a lighting device that is excellent in power saving effect and long detection distance, so that there is no fear of malfunction even if installed in a high place.

In order to achieve the above object, the lighting apparatus according to the present invention is a lighting apparatus comprising a lamp and a cover, and controls the lighting and turning off of a lamp by detecting the presence or absence of a human body using electromagnetic waves in a microwave band inside the cover. Microwave operation sensor module is characterized in that the built-in.

In the lighting device, when the lamp is an incandescent lamp or a halogen lamp, the lamp is directly powered by the microwave operation sensor module and is turned on. When the lamp is a fluorescent lamp, the microwave operation sensor module and the fluorescent lamp are turned on. Between is characterized in that the ballast is further provided with a power supply according to the output of the microwave sensor module to control the lighting of the fluorescent lamp.

The microwave operation sensor module may include a power supply unit receiving commercial AC power and converting the same into a predetermined DC voltage; A signal amplifier for amplifying the detected signal using the microwave sensor; A comparison circuit unit which determines whether humans or animals are present by comparing whether the voltage inputted through the signal amplifier is greater than or equal to a set value; And an output circuit unit for outputting a signal for turning on or off a lamp according to the output of the comparison circuit unit.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a view showing the external structure of the lighting apparatus according to an embodiment of the present invention.

As shown, the lighting apparatus according to the present invention is a conventional type lighting apparatus comprising a lamp 200, the cover 100 constituting the appearance, the microwave sensor module in the interior of the cover 100 300 is made of a built-in configuration.

The microwave operation sensor module 300 oscillates a high frequency of 1 ~ 30GHz band by using a microwave sensor to project it on the object and then amplify the difference in the frequency coming back from the object to detect the presence and movement of people, etc. Afterwards, the on / off operation of the lamp 200 is controlled according to the result.

While the conventional sensor and the like to detect the presence of the human body, etc. using an infrared sensor, the present invention has a feature that is less affected by changes in the environment and excellent in precision and applicability because it employs a microwave sensor. In addition, as long as the cover 100 is made of non-metals, the sensor can detect the presence or absence of an external person while being embedded in the inside of the cover, so that the design of the lighting device can be diversified, unlike conventional infrared sensors. There is an advantage to that.

 On the other hand, Figure 1 (a) shows a structure in which the microwave operation sensor module 300 is installed in a three-wavelength lamp or incandescent lamp, Figure 2 (b) requires a ballast 400 for the lighting operation, such as fluorescent lamps It shows a structure in which the microwave operation sensor module 300 is applied to the discharge lamp.

As shown in Figure 1, commercial AC voltage AC 120 ~ 240V is supplied to the power of the microwave operation sensor module 300, when the power is supplied to the sensor module to operate after waiting for a set time of approximately 3 ~ 6 seconds. do. At this time, the operating power range of the sensor module is 4 ~ 6V. After the setting is completed, if a person or an animal is detected, the lamp 200 is immediately turned on in the case of FIG. 1 (a), and in the case of FIG. 1 (b), after supplying power to the ballast 400 for a predetermined time. The lamp 200 is controlled to be turned on by the ballast.

Figure 2 is a block diagram showing an embodiment of a microwave operation sensor module embedded in the lighting apparatus of the present invention, Figure 3 is a circuit diagram of the microwave operation sensor module.

As shown, in the lighting apparatus according to the present invention, the microwave operation sensor module 300 is largely the power supply unit 10, the detection signal amplification unit 20, the comparison circuit unit 30, the output circuit unit 40 It is distinguished by.

The power supply unit 10 is a circuit for converting a voltage input at a commercial AC voltage of AC 120V to 240V into a predetermined DC voltage, for example, DC 5.0V and outputting the same.

The sensing signal amplifier 20 is a circuit unit that receives an output voltage from the power supply unit 10 and amplifies a signal detected by using a microwave sensor.

Figure 4 shows an embodiment of a microwave sensor applied to the sense signal amplifier 20 of the present invention.

As shown in FIG. 4, the microwave sensor connected to the signal amplifier 20 includes a dielectric resonator oscillator 201, a microwave mixer 202, and patch antennas 203 and 204. It has four terminals (+ 5V, IF, GND) for connecting to amplification circuit.

Microwaves projected onto an object through an antenna generate a Doppler shift at the IF terminal when the human body is in motion. The amount of Doppler shift is proportional to the reflection of the transmitted energy and is in the region of microvolts, and a high gain low frequency amplifier is connected to the IF terminal to amplify this Doppler shift to a processable level.

This will be described with reference to FIGS. 2 and 3 again. That is, the Doppler shift detected by the microwave sensor is amplified by a two-stage operational amplifier (OP_AMP) and used to determine the presence and movement of humans or animals. The amplification degree represents an amplification rate of (1 + R8 / R10) in the first non-inverting amplification stage, and an amplification rate of (R11 / R9) in the second inverting amplification stage.

On the other hand, it is possible to adjust the sensitivity by configuring the resistor (R9) with a variable resistor, in which case the output from the non-inverting amplifier stage is fixed and the output of the inverted amplifier stage is variable. The overall amplification rate is determined by the product of the amplification rate of the non-inverting amplification stage and the width ratio of the inverting amplification stage.

In addition, it is configured to have a band pass filter (BPF) function consisting of a resistor and a capacitor in order to detect only the human body or animals as much as possible. Here, the low cutoff frequency f ₀ L is determined by the equation f ₀ L = 1/2 pi C8R10 and the high cutoff frequency f ₀ H is expressed by f ₀ H = 1/2 pi C6R8.

The comparison circuit unit 30 is composed of a window comparator circuit and compares whether the change in voltage input through the signal amplifier unit 20 is greater than or equal to a set value to determine the presence or absence of a human or animal, and It is a structure which makes it possible to have a non-sensing width with the change of the signal detected by a sensor so that a detection error may not occur.

+ 3.3V is supplied to the positive input as the reference voltage on pin 5 of U1 (LP2902N) and has an upper limit voltage detection circuit. Therefore, if the voltage of negative input terminal (No. 6 pin of U1) becomes less than + 3.3V, the output becomes high level, and if the voltage of negative input terminal (No. 6 pin of U1) becomes more than + 3.3V The output suddenly goes to a low level.

+ 1.7V is supplied to the negative input terminal as the reference voltage on pin 2 of U1 and the minimum voltage detection circuit is provided. Therefore, if the voltage of positive input terminal (pin 3 of U1) is + 1.7V or higher, the output will be high level, and if the voltage of positive input terminal (pin 3 of U1) is lower than + 1.7V, the output will be abruptly low level. It becomes + 2.5V is supplied to the negative input terminal of pin 6 of U1 and the positive input terminal of pin 3 of U1.

And when the microwave sensor detects human movement, this voltage changes. If either pin 7 of U1 or pin 1 of U1 goes low, the output goes low. Diodes (SD1, SD2) at the output of pin 7 of U1 and pin 1 of U1 are to prevent overcurrent from flowing from the other side when one output goes low level.

The output circuit unit 40 is a circuit for outputting a signal for turning on or off the lamp according to the output of the comparison circuit unit 30. In the present invention, when the sensor detects the movement of the human body, the output of the comparison circuit unit (pin 1 of U1) is at a low level. In the output circuit unit 40, the Schmitt trigger circuit (Hex Schmitt Trigger) is applied to light the lamp with this signal.

First, if the input of pin 1 of U2 (MC14584D) is at a low level, a + 5V high signal is output from pin 2 of U2, and is rapidly charged in capacitor C11 by passing diode SD3. At the same time as charging, low signal is output at pin 4 of U2 and high signal is output at pin 6. This high signal triggers U3 (optocoupler MOC3021), which is the gate signal of the triac (TRI1: BTA06). Due to the nature of the triac, if a signal is present at the gate, it is always turned on. The low signal input time on pin 1 of U2 is very short, so the lamp does not turn on.

To compensate for this, the circuit configuration of C11 and R18 was added. As a result, C11 is rapidly charged through SD3 when a human motion is detected, and a low signal is applied to pin 2 when there is no human or no motion. At this time, C11 is gradually discharged by R18, and this discharge time is the time when the lamp is turned on. This discharge time, that is, the lighting time of the lamp, can be adjusted by configuring R18 with a variable resistor. Also, in the output circuit section 40, the optocoupler U3 (MOC3021) was used to control a load having AC as an input power source with a potential difference and a DC signal on the triac TRI1 and the circuit.

Looking at the characteristics of the lighting device with a built-in microwave operation sensor module as described above are as follows.

(1) It can be applied to any lighting with non-metallic cover. That is, the conventional illumination lamp using the infrared sensor can overcome the problem that the diversity of design design was limited because the cover portion made of acrylic, glass, etc. had to be exposed to expose the sensor unit.

(2) There is sufficient power saving effect because standby power is within 1.5W. Due to the characteristics of the sensor lighting, when the power is turned on, the sensor stage always receives a constant standby voltage or a sensor-powered reserve power. When a human body is detected, a voltage is generated and the standby voltage is turned on due to this voltage. The lighting apparatus of the present invention can achieve power savings due to the relatively low standby voltage.

(3) It is not detected except humans or animals and is not affected by the surrounding environment. Since the lighting apparatus of the present invention has a band pass filter function, there is an advantage that the detection error is small because it is not restricted by surrounding objects.

(4) It can operate without error even if the sensing distance is installed at a relatively high place such as 5m.

(5) When the movement of the object continues, it is always on. When the movement stops, it is turned off after a certain time, which saves energy.

In the above, the present invention has been shown and described with respect to certain preferred embodiments. However, the present invention is not limited to the above-described embodiments, and those skilled in the art to which the present invention pertains can variously change variously without departing from the technical spirit of the present invention described in the following claims. You can do it.

According to the lighting device of the present invention, by embedding a microwave motion sensor module (Microwave Motion-Sensor Module) as a sensor module to detect the movement of the human body without controlling the sensor to the outside of the cover of the lighting device to control the lighting and turn off. In this way, the design of the lighting device can be diversified regardless of the installation position of the sensor unit.

In addition, the lighting device of the present invention is excellent in power saving effect and has a long detection distance has the advantage that can be operated precisely without malfunction even if installed in a high place.

Claims (7)

In the lighting device consisting of a lamp and a cover, Illumination device, characterized in that the microwave operation sensor module for controlling the lighting and turning off of the lamp by detecting the presence of the human body using the microwave of the microwave band in the cover. The method of claim 1, The lamp is an incandescent lamp, a halogen lamp, the lighting device, characterized in that the light is directly supplied by the microwave operation sensor module, The method of claim 1, The lamp is a fluorescent lamp, illumination between the microwave operation sensor module and the fluorescent lamp is further provided with a ballast for controlling the lighting of the fluorescent lamp by receiving power according to the output of the microwave operation sensor module Device. The method according to claim 2 or 3, The microwave operation sensor module, A power supply unit receiving commercial AC power and converting the same into a predetermined DC voltage; A signal amplifier for amplifying the detected signal using the microwave sensor; A comparison circuit unit which determines whether humans or animals are present by comparing whether the voltage inputted through the signal amplifier is greater than or equal to a set value; And an output circuit unit for outputting a signal for turning on or off the lamp according to the output of the comparison circuit unit. The method of claim 4, wherein The signal amplifier includes a two-stage operational amplifier (OP-AMP) to amplify the signal, the input of the operational amplifier of the second stage lighting device, characterized in that the variable resistor (R9) for adjusting the sensitivity is provided. The method of claim 5, The output circuit unit has a Schmitt trigger circuit (Hex Schmitt Trigger), the Schmitt trigger circuit is a lighting device, characterized in that the capacitor (C11) and the resistor (R18) is connected to adjust the lighting time of the lamp. The method of claim 6, The resistor (R18) is a variable device, characterized in that the variable resistor.

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