KR20040008244A - Sensor Lamp Interface With New Light Source - Google Patents

Abstract

PURPOSE: A sensor lamp interface using a new light source is provided to maximize the quantity of light and minimize the power consumption by substituting the new light source for an existing lamp. CONSTITUTION: A sensor lamp interface using a new light source includes an LED lamp(100), a power supply(140), a first and a second sensors(110,120), a source(130), a microprocessor(150), and a device(160). The LED lamp(100) is formed with an LED or a new lamp source. The power supply(140) is installed at the LED lamp(100). The first and the second sensors(110,120) are installed at one side of the LED lamp(100). The source(130) is installed at one side of the LED lamp(100). The microprocessor(150) is installed at one side of the new lamp in order to process signals of the first and the second sensors and the source(130). The device(160) is installed at one side of the LED lamp in order to process a signal of the microprocessor(150).

Description

Sensor Lamp Interface With New Light Source

In general, corridors or porches are used to detect the human body door sensor to control the lamp by the PIR (Passive Infra-Red Sensor). However, since the sensor lamp uses an incandescent lamp or a fluorescent lamp, it is difficult to form the sensor unit and the bulb unit as one body part.

Incandescent lamps are used in buildings, and reversing lamps, taillights, and brake lamps are used in vehicles. Such a lamp is a filament-type light bulb, and is used while being mounted in a space enclosed by a case and a lens. However, the filament lamp has the following problems. That is, in the conventional filament lamp, the filament is heated when the power is applied, and thus the temperature is radiated to emit light. Therefore, it takes a predetermined time from the time of power supply to the temperature radiation, there is a problem that the response is inferior.

In addition, there is a problem that the life of the lamp is reduced by maintaining the high temperature of the sealed space by the heat generated from the lamp, and the maintenance and repair costs are increased due to frequent replacement of parts.

The present invention has been made to solve the above-mentioned problems, the object of the present invention is to provide a lamp unit and a sensor unit on one side of the lamp unit using the LED or the new light source having a very high responsiveness as well as a small amount of heat generated during lighting. By constructing a circuit that operates in parallel, by implementing a sensor lamp in which the sensor's detection signal and the lamp's light emission signal can be integrated into one, it prevents excessive generation of heat and improves the durability of the parts. It is to provide a sensor lamp interface using a new light source that can be integrated to reduce maintenance costs.

Still another object of the present invention is to provide a sensor lamp using a LED or a new light source as a light source, which can be used as it is mounted in a conventional socket.

1 is a block flow diagram illustrating the principle flow of the present invention.

Figure 2 is a perspective view showing the appearance of the sensor lamp according to the present invention.

3 is a cross-sectional view of a sensor lamp according to the present invention.

4 and 5 are cross-sectional views showing the angle of light emission of the sensor lamp according to the present invention.

Figure 6 is an exploded view showing the internal assembly state of the sensor lamp according to the present invention.

7 is a perspective view of the light emitting unit and the sensor unit of the sensor lamp according to the present invention.

8 is a connection circuit diagram of the LED used in the present invention.

9 is an operation circuit diagram of a pyroelectric infrared sensor (PIR) used in an embodiment of the present invention.

10 is a circuit diagram of a motion sensor used in an embodiment of the present invention.

11 is an internal structure diagram of the LED used in the present invention.

* Description of the symbols for the main parts of the drawings *

10 lamp 20 cap

23, 25: Fresnel Lens

26, 160: Device 27: Sensor

30: body 40: LED (LED)

50: main board 60: connection board

63: socket 70: horizontal substrate

80: elastic piece 100: lamp (Lamp)

110: first sensor 120: second sensor

130: source 140: power supply

150: micro processor for controlling all operations (Micro Processor)

Hereinafter, a sensor lamp interface using the new light source of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flow chart of a processor showing the principle flow of the present invention, Figure 2 is a perspective view showing the appearance of a sensor lamp using a new light source according to the present invention. 3 is a cross-sectional view of a sensor lamp, and FIGS. 4 and 5 are cross-sectional views showing angles at which the sensor lamps emit light. FIG. 6 is an exploded view illustrating an internal assembly state of the sensor lamp, and FIG. 7 is a perspective view illustrating a light emitting unit and a sensor unit of the sensor lamp. 8 is a connection circuit diagram of the LED, Figure 9 is a circuit diagram showing the operation principle of the pyroelectric infrared sensor (PIR) used in an embodiment of the present invention, Figure 10 is a motion detector used in an embodiment of the present invention (Motion Sensor) is an overall circuit diagram, Figure 11 is a perspective view showing the internal structure of the LED.

In general, a conventional lamp using a filament is composed of a case and a lens and mounted in a closed space, so that when the power is applied, the filament is heated, and thus the temperature is radiated to emit light. Therefore, when the power is applied, it takes a predetermined time until the temperature is radiated, and thus the response is deteriorated. As a result, the life of the lamp is reduced by maintaining the high temperature in the closed space by heat generated from the lamp. Due to frequent parts replacement, there was a problem in that the maintenance cost increased.

Therefore, the present invention has a structure that replaces the lamp with a new light source such as an LED to maximize the amount of light and consume less power, and also has a function of parallel processing of the response signal by mounting one or more sensors on one side of the lamp. It consisted of the circuit which added.

Referring to FIG. 1, in a general lamp having a lamp unit and a socket unit that emit light of a predetermined illuminance value by receiving a constant voltage power from an external source, a new lamp unit replacing a general lamp such as an incandescent lamp or a fluorescent lamp with an LED or a new light source ( 100); A power supply unit 140 that operates as an input power source of the lamp and supplies it to one side of the lamp to supply power to the present invention; A sensor unit (110,120) for mounting at least one sensor on one side of the light for use for sensing purposes; A source unit (130) for mounting at least one source device on one side of the lamp to process an input signal; A microprocessor unit 150 mounted on one side of the lamp and capable of processing all control signals together with signals generated from the sensor unit or the source unit; It is mounted to one side of the light, characterized in that consisting of a device unit 160 for processing a control signal of the microprocessor unit.

2, the socket portion 63 is not limited to a screw type (SL-2 in FIG. 2) that is engaged by turning a fitting method of fixing a lamp, and a flange type (SL in FIG. 2) that is pushed and rotated. -1) or a coupling method of a general lamp, such as various coupling methods as shown in FIG.

In FIG. 2, the cap 20, which is an outer surface of the new lamp unit, includes Fresnel lenses 23 and 25 to efficiently transmit light generated by an LED or a new light source at a specific wide angle. It can be characterized. The Fresnel lens refers to a lens that can achieve the same wide angle as the convex and concave lenses by realizing various spherical surfaces in a thin flat transparent material unlike ordinary convex or concave lenses.

In order to explain the present invention having the above configuration in more detail, some detailed embodiments and operations will be described below.

<Example 1>

In the embodiment described above, the present invention is applied and improved to a general motion detection hall for controlling power by sensing an entrance and exit of a human body.

As shown in FIG. 1, when the first sensor 110, which is a passive infra-red sensor, senses an operation state of a person and sends this signal to the microprocessor 150, the microprocessor sends a control signal. Send to the new lamp unit 100 to control the light source (On / Off). Until now, except for replacing the light source with a new light source, the same principle as that of the existing motion detection hall and the like is omitted.

In one embodiment of the present invention additionally by adding a fire detection sensor to the second sensor 120 for the purpose of detecting the human body as described above, at least one sensor for detecting a fire situation (flame, smoke, high temperature, etc.). Addition) is detected and sent to the microprocessor 150, the control signal processed in the microprocessor is sent back to the device 160, the alarm will sound.

If the alarm is misleading, the infrared signal generated by pressing any button of the remote controller for more than 0.5 seconds using a remote controller commonly used in homes is emitted to the present invention. The source unit 130, which is composed of an Infra-Red Receiver of the present invention, receives this signal and sends a reset signal for the misinformation to the microprocessor 150. The control signal is sent to the device 160 to cancel the alarm.

In this case, the reason why the remote control is pressed for 0.5 seconds or more is to prevent the source unit 130 from malfunctioning by an infrared signal generated when the remote control is used to operate a TV. As described above, it is preferable to add a timer circuit to the sensor unit 110 or 120 or the source unit 130 to operate the timer only when the input signal is input for 0.5 seconds or more.

In this case, the device 160 may be configured as a buzzer or a speaker that sounds an alarm, and may be replaced by a radio frequency transmitter to perform a function of wirelessly notifying a fire situation to the outside.

In addition, a third sensor can be added to facilitate detection of other situations (gas leak, etc.), and instead of pressing any button of the general remote control for more than 0.5 seconds, a specific signal (for example, buttons of 1 and 9 of the general remote control) can be used. The source unit 130 may be operated by firing a combined signal).

<Example 2>

Referring to the first embodiment, as in the first embodiment, it is also possible to add a voice recording / autoplay circuit while performing the same function as the human body detection hall, but to another family at the entrance where the present invention is installed. In order to record the transmission details, while performing the same function as the human body detection entrance, the microphone (voice input circuit unit) is mounted on the source unit 130 of FIG. When firing to the sensor 120, the second sensor, which is an infrared ray receiver (Infra-Red Receiver) detects a remote control signal and sends a detection signal to the microprocessor 150, the control signal from which the microprocessor is operated is the The microphone 130 is sent to the source unit 130 with a microphone to perform a recording function. The voice signal recorded in this manner is subsequently used by the micro pro sensor when the human body detection light is turned on. Upon recognizing this, the control signal is sent to the device 160, and the recorded content is reproduced by the speaker of the device configured as the voice output circuit.

At this time, if you want to delete the recorded message, press any button of the general remote control again for more than 0.5 seconds to emit infrared light toward the second sensor 120, the second sensor that recognizes this to perform a cancel function. do. In other words, the second sensor, which is an Infra-Red Receiver, performs a recording function by a signal of a remote controller sent to the primary, and once the second sensor is sent by pressing a button of the remote controller, the second sensor detects this. To perform the delete function.

As described in the above two embodiments, those skilled in the art will be able to easily make various modifications using the principles of the present invention. For example, if the back light of a car is replaced with the present invention, a pyroelectric infrared sensor or a proximity sensor, which is equipped with a person or a barrier behind the sensor lamp of the present invention, may detect this and generate a danger alarm or approach distance. When applied to the taillight of the vehicle, the illumination sensor attached to the sensor lamp of the present invention controls the light by looking at the amount of ambient light and off the lamp (Off) to protect the discharge of the vehicle battery Various embodiments of the present invention may be devised, and thus, the present invention is not limited only to the two exemplary embodiments as described above.

As described in detail in the configuration of the invention, according to the present invention by replacing the existing lamp with an LED or a new light source may have an efficient structure that maximizes the amount of light and consumes less power, and also at least one on one side of the lamp By adding a sensor to parallel process the response signal, two or more functions can be realized in a single body, thereby reducing the cost.

By using the present invention, a low-cost, high-efficiency device can be realized in home automation and telematics since the detection functions such as distance detection, theft detection, and fire detection, and alarm and notification functions are integrated at the same time while obtaining a light source. have.

Claims (4)

In a lamp having a lamp portion and a socket portion that emits light of a specified illuminance value by receiving a constant voltage power from the outside, A new lamp unit (100) for replacing the lamp unit with an LED or a new light source; A power supply unit 140 that operates as an input power source of the lamp and is mounted on one side of the lamp; Sensor units (110 and 120) for mounting at least one sensor on one side of the lamp; A source unit (130) for mounting at least one source device on one side of the lamp; A microprocessor unit 150 mounted on one side of the lamp to process signals generated from the sensor unit or the source unit and input / output signals; The sensor lamp interface using a new light source, characterized in that the device is mounted on one side of the lamp to process the signal sent from the microprocessor unit (160). The method of claim 1, wherein the socket portion, The sensor lamp interface using a new light source, characterized in that not limited to the screw type to be coupled by turning the fitting method of the lamp, it is configured by selecting any one of a variety of coupling methods or a flange type or push and turn coupling. According to claim 1, wherein the new lamp unit 100, The sensor lamp interface using a new light source, characterized in that the Fresnel lens to the outer surface of the new lamp portion to efficiently transmit the light generated from the LED or the new light source. According to claim 1, wherein the sensor unit 110, 120 or source unit 130, The sensor lamp interface using a new light source, characterized in that only when the input signal is input for more than 0.5 seconds by adding a timer circuit to the sensor unit or the source unit.