KR101065621B1 - High efficiency energy saving led light fixture with sensor module - Google Patents

Abstract

The present invention provides a printed circuit board including a light emitting diode driving circuit and a switch mode power supply (SMPS); A circuit housing having a through hole connecting the SMPS to an AC power input system while accommodating the printed circuit board; Heat dissipation is formed in the straight metal plate for the heat dissipation, the circuit housing is coupled to the upper center; A light emitting diode module in which a light emitting diode controlled by the light emitting diode driving circuit is linearly disposed on a straight substrate that is heat bonded to the inside of the heat sink; A straight reflection plate coupled to both inner end surfaces of the lower end of the heat sink to maintain a predetermined reflection angle in a side direction; A PC cover coupled to a lower end of the heat sink to protect and protect the light emitting diode module and the linear reflecting plate, prevent glare, and diffuse light; A sensor module composed of an infrared sensor embedded in a sensor case coupled to one side of the heat sink and a sensor lens for condensing a lower infrared signal with an infrared sensor to detect a movement of an object at the bottom and to send a signal to a power supply unit; A life display indicator unit configured to display an LED lifetime of the light emitting diode module by forming a life detection circuit of the light emitting diode and an LED life display unit on an indicator circuit board embedded in an indicator case coupled to the other side of the heat sink; It is coupled to the top of the heat sink is connected to the spring tension to attach the entire device to the fixed structure; relates to a super low-power LED fixed luminaire comprising a.

Description

High Efficiency Energy Saving LED Light Fixture with Sensor Module

The present invention provides a printed circuit board including a light emitting diode driving circuit and a switch mode power supply (SMPS); A circuit housing having a through hole connecting the SMPS to an AC power input system while accommodating the printed circuit board; Heat dissipation is formed in the straight metal plate for the heat dissipation, the circuit housing is coupled to the upper center; A light emitting diode module in which a light emitting diode controlled by the light emitting diode driving circuit is linearly disposed on a straight substrate that is heat bonded to the inside of the heat sink; A straight reflection plate coupled to both inner end surfaces of the lower end of the heat sink to maintain a predetermined reflection angle in a side direction; A PC cover coupled to a lower end of the heat sink to protect and protect the light emitting diode module and the linear reflecting plate, prevent glare, and diffuse light; A sensor module composed of an infrared sensor embedded in a sensor case coupled to one side of the heat sink and a sensor lens for condensing a lower infrared signal with an infrared sensor to detect a movement of an object at the bottom and to send a signal to a power supply unit; A life display indicator unit configured to display an LED lifetime of the light emitting diode module by forming a life detection circuit of the light emitting diode and an LED life display unit on an indicator circuit board embedded in an indicator case coupled to the other side of the heat sink; It is coupled to the top of the heat sink is connected to the spring tension to attach the entire device to the fixed structure; relates to a super low-power LED fixed luminaire comprising a.

The present invention relates to a fixed luminaire using a light emitting diode, and more particularly, to detect a light emitting diode having a wide range of voltage characteristics and capable of high brightness and to detect a motion at a maximum output only when the object is moved, and to minimize the movement of the object. The present invention relates to an integrated luminaire equipped with a power supply control unit including a sensor module for maintaining standby power, an indicator for knowing the useful life in advance, and a fixing member for easily installing the luminaire.

There may be several types of luminaires, depending on the environmental requirements of the place requiring 24 hours of continuous lighting. In particular, places such as underground car parks have complex environmental conditions in which time zones in which traffic is concentrated and time zones that are difficult to move are clearly clear and cannot be artificially controlled properly. .

In recent years, when social interest and demand for energy-saving luminaires are being raised, as a countermeasure for developing a conventional passive luminaire into an active energy-saving active luminaire, motion detection technology, output control technology, and useful life prediction technology are merged. In the case of installation, it is desirable to simplify the cumbersome working conditions.

In addition, conventional luminaires have required frequent replacement and maintenance despite high power consumption. Fluorescent lamps, which are used as light sources, are manufactured from a regulated material, which is urgently needed to replace them in the future. There is a demand for a countermeasure around the world.

In addition, the conventional luminaires have a safety hazard under conditions that do not know when to turn off, it is desirable to prevent the accident in advance by replacing the aging product in advance by predicting the life after long-term use.

On the other hand, products that mimic the shape of existing fluorescent lamps and replace only light sources with LEDs have been released in recent years, but this was recognized as a safety problem by the National Institute of Technology and Standards, and it was announced that LED fluorescent lamps using G13 base could not be used. Since the technical standard for this is expected in 2011, there is a need for a rational proposal to solve these safety problems.

Disclosure of Invention The present invention has been made to solve the above problems, and aims to provide an ultra-low power LED fixing luminaire which minimizes power consumption, maximizes the service life, and displays the available remaining time on the display unit to prevent sudden extinction. It is done.

In addition, the present invention eliminates the discomfort caused by the change in illuminance to the user, grants the installer a minimum maintenance cost, and adopts a fixing member designed to be easily installed under various working conditions in which the fixture fixture is not standardized, It is an object of the present invention to provide an ultra-low power LED fixed luminaire that saves the most cost and time.

In order to achieve the above object, the present invention provides a printed circuit board including a light emitting diode driving circuit and a switch mode power supply (SMPS); A circuit housing having a through hole connecting the SMPS to an AC power input system while accommodating the printed circuit board; Heat dissipation is formed in the straight metal plate for the heat dissipation, the circuit housing is coupled to the upper center; A light emitting diode module in which a light emitting diode controlled by the light emitting diode driving circuit is linearly disposed on a straight substrate that is heat bonded to the inside of the heat sink; A straight reflection plate coupled to both inner end surfaces of the lower end of the heat sink to maintain a predetermined reflection angle in a side direction; A PC cover coupled to a lower end of the heat sink to protect and protect the light emitting diode module and the linear reflecting plate, prevent glare, and diffuse light; A sensor module composed of an infrared sensor embedded in a sensor case coupled to one side of the heat sink and a sensor lens for condensing a lower infrared signal with an infrared sensor to detect a movement of an object at the bottom and to send a signal to a power supply unit; A life display indicator unit configured to display an LED lifetime of the light emitting diode module by forming a life detection circuit of the light emitting diode and an LED life display unit on an indicator circuit board embedded in an indicator case coupled to the other side of the heat sink; A connection portion coupled to the top of the heat sink by a spring tension to attach the entire device to the fixed structure, wherein the sensor module adjusts the infrared detection angle toward the front of the luminaire so as to pre-detect the object approaching the bottom of the luminaire. The LED driving circuit may illuminate the LED at maximum brightness in advance according to a detection signal of the sensor module, maintain the maximum brightness for a predetermined time after the object passes, and switch to the minimum brightness LED. Fixed luminaires are considered as technical points.
Here, the life detection circuit of the life display indicator unit accumulates the maximum output driving time of the light emitting diode in real time, and the LED life display unit is composed of green, red, and yellow LEDs to display color classification according to the life state. It is desirable to be an ultra-low power LED fixed luminaire, characterized in that it is possible to know in advance the available time and replacement time.

delete

delete

According to the present invention described above, there is an advantage of providing an ultra-low power LED fixed luminaire that minimizes power consumption, maximizes the useful life, and displays the available remaining time on the display unit to prevent sudden extinction.

In addition, the present invention eliminates discomfort due to changes in illuminance and confers minimization of maintenance costs to installers, and can be easily installed under various working conditions where standardization of luminaire fixtures is not achieved. There is an advantage that an ultra-low power LED fixed luminaire is provided.

1 is a circuit diagram of a luminaire using a light emitting diode according to the present invention.
2 is a block diagram of a luminaire using a light emitting diode according to the invention.
3 is an assembly view of a luminaire using a light emitting diode according to the present invention.
4 is an exploded perspective view of a luminaire using a light emitting diode according to the present invention.
5 is a perspective view of a luminaire using a light emitting diode according to the present invention;
6 is an operation explanatory diagram according to the present invention.
7 is an exploded perspective view of a sensor module unit according to the present invention

Hereinafter, the present invention will be described with reference to the drawings. In the following description of the present invention, a detailed description of related arts or configurations will be omitted when it is determined that the gist of the present invention may be unnecessarily obscured will be.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to be exemplary, self-explanatory, allowing for equivalent explanations of the present invention.

1 is a circuit diagram of a luminaire using a light emitting diode according to the present invention, Figure 2 is a block diagram of a luminaire using a light emitting diode according to the present invention, Figure 3 is a luminaire using a light emitting diode according to the present invention 4 is an exploded perspective view of a luminaire using a light emitting diode according to the present invention, FIG. 5 is a perspective view of a luminaire using a light emitting diode according to the present invention, and FIG. 7 is an exploded perspective view of a sensor module unit according to the present invention.

As shown in FIG. 2 and FIG. 4, the present invention generally includes a printed circuit board 40, a circuit housing 400, and a heat sink 10 in which a light emitting diode driving circuit 40a and a switch mode power supply (SMPS) 40b are formed. ), The light emitting diode module 30, the linear reflector 10a, the PC cover 20, the sensor module 60, the life indicator indicator unit 50, and the connection unit 70.

As shown in FIG. 6, the operation principle of the present invention is a luminaire for adjusting the light output by detecting the movement of an object in advance.

According to the present invention, the sensor module 60 is installed on one side of the heat sink 10, the life indicator indicator 50 is installed on the other side of the heat sink 10, and the light emitting diode driving circuit is mounted on the top of the center of the heat sink 10. The circuit housing 400 protecting the furnace 40a and the printed circuit board 40 on which the SMPS 40b (Switch Mode power Supply) is formed is coupled, and the light emitting diode module 30 is coupled to the bottom of the heat sink 10. do.

As shown in FIG. 5, the heat sink 10 is formed with irregularities for heat dissipation at an upper end thereof, and connects the SMPS 40b to an AC power input system while accommodating the printed circuit board 40 at an upper center part. The through hole 40d is configured to be a luminaire body to which the circuit housing 400 formed while being protected by the bushing 40c is coupled.

The light emitting diode driving circuit 40a of the present invention is a circuit part for controlling the light emitting diode module 30. When the movement of an object is detected by the sensor module 60, the light emitting diode is driven to the maximum brightness (18W). When the lamp is turned on and there is no movement, it automatically switches to the ultra low power mode (5W) after 10 seconds to provide the power saving effect of the present invention.

When the sensor module 60 detects a continuous motion, the maximum brightness of the sensor module 60 is continuously maintained, and 10 seconds after the last object passes, the device enters the ultra low power standby mode.

Ultra low power standby mode of the present invention has the feature to maintain the illumination capable of shooting, such as CCTV.

In the embodiment shown in FIG. 1, the LED driving circuit 40a drives the MICRO-CONTROLLER circuit and the LED to control main functions such as mode selection, lifetime display, LED brightness, etc., for selecting a sensor mode and a lamp mode. This circuit is composed of LED driver which has constant current driving and dimming function.

The SMPS 40b is coupled to an external wire connected to a commercial power line to stably supply the operating power of the LED module 30.

The SMPS 40b is a device for supplying power to the light emitting diode module 30 and each circuit, and has a high-efficiency, high-reliability circuit of a switching type, and includes overvoltage protection and a short protection circuit.

In detail, the SMPS 40b includes an AC input filter unit for suppressing a sudden overvoltage of an input power supply, a AC-DC converter for converting an input AC voltage passed through the AC input filter unit into a DC voltage, and the AC-. DC output voltage stabilized output voltage converted by the DC converter to supply to the light emitting diode, DC output to adjust the output voltage by PWM control the AC-DC converter based on the voltage value fed back from the DC output voltage It is configured with a voltage controller.

The DC output voltage controller may include a switching regulator SR1 for detecting an output voltage of the DC output voltage part, a photo coupler U2 switched on / off by the switching regulator SR1, and the photo coupler U2. It is composed of a control IC (U1) for outputting a PWM control signal to the AC-DC converter based on the signal input by the switch action.

The SMPS 40a configured as described above can be used at a wide range of voltages of AC 90V to 260V, and is designed to be turned on even at temperatures from -30 to +60.

The light emitting diode module 30 includes a light emitting diode controlled by the light emitting diode driving circuit in a straight line on a straight substrate mounted with a heat adhesive inside the heat sink 10. It consists of

The light emitting diode module 30 is provided in plural, and is mounted by surface-mounting (SMT) a high brightness light emitting diode that meets the minimum required illuminance.

The sensor module 60 of the present invention is a sensor lens 60c for condensing the infrared sensor 60b and the bottom infrared signal to the infrared sensor 60b, which are embedded in the sensor case 60d coupled to one side of the heat sink 10. It is composed of a circuit part that detects the movement of the object at the bottom and sends a signal to the power supply.

The sensor module 60 of the present invention has a basic configuration of the PIR sensor, the PIR sensor is a device for capturing the movement of an object, such as a human body, an animal, a car by infrared rays and converting it into an electrical signal, as shown in FIG. The detection range has a detection angle of 120 ° and a detection distance of 5m.

The sensor module 60 includes a sensor amplifier in the circuit to amplify the weak signal of the PIR sensor.

Specifically, the sensor module 60 may include a sensor printed circuit board 60a, a sensor 60b, and a sensor lens 60c for making the detection uniform and widening the sensing angle, as shown in FIGS. 4 and 7. Consists of, the sensor case (60d) material is injection molded into a flame retardant PBT.

The position of the sensor module 60 is installed on the outer peripheral slope of one side end of the heat sink 10 to maximize the pre-sensing angle and distance of the access object.

The sensor module 60 adjusts an infrared ray sensing angle toward the front of the luminaire so as to enable pre-sensing of an object approaching the lower end of the luminaire of the present invention, and the LED driving circuit illuminates the LED at maximum brightness in advance. After passing, the object maintains the maximum brightness for the set time and then switches to the minimum brightness.

The pre-sensing angle of the sensor module 60 is preferably set to an inclination angle of about 15 degrees.

The life indicator indicator unit 50 of the present invention includes a life detection circuit and an LED lifetime indicator of the light emitting diode module 30 on an indicator circuit board 50a that is embedded in an indicator case () coupled to the other side of the heat sink 10. A circuit portion 50b is formed to display a light emitting diode usable life of the light emitting diode module 30. The LED life display portion 50b is composed of green, yellow, and red LEDs, based on the maximum light emission time of the LED. The green LED is turned on for 0 ~ 20,000 hours, the yellow LED is turned on for 20,000 ~ 30,000 hours, and the red LED is turned on after 30,000 hours.

In the present invention, the life detection circuit of the life display indicator unit 50 calculates the maximum output driving time of the light emitting diode module 30 in real time, and displays the color classification according to the life state of the LED life display unit 50b. Make sure you know when the luminaire will be available and when to replace it.

The PC cover 20 is a linear protective plate coupled to the bottom of the heat sink 10, and protects the LED module 30 and the linear reflector (10a) by housing, to prevent glare and to diffuse light.

In the present invention, the PC cover 20 is cut into the cross-section of the material extruded with a polycarbonate material added with a light diffusing agent in the cross section to fit the length of the device and inserted into the groove of the heat sink 10 using the inherent tension of the material and thickness 1.2 Maintain the robustness of falling out over mm.

The heat sink 10 of the present invention is for efficiently dissipating heat emitted from the plurality of light emitting diode modules 30, the heat sink 10 is a plurality of heat dissipation to the outer periphery as shown in FIG. A heat dissipation groove is formed, and the PC cover 20 is fastened to the lower end of the heat dissipation plate 10.

Therefore, a recess may be formed at the lower portion of the heat sink 10 to be coupled to the PC cover 20, and protrusions corresponding to the recess of the heat sink 10 may be formed at both ends of the PC cover.

The heat sink 10 is pressed into the PC cover 20 is mounted, it can be mounted after pressing the groove in the vertical direction of the heat sink 10 to the projection of the PC cover 20.

On the inner end of the heat sink 10, the light emitting diode module 30 is mounted on the center line using a thermal adhesive, and a power line through hole 10b through which a power line connecting the same is passed, and a reflecting plate 10a is formed. Adhesively and horizontally applied to the inside of the heat sink 10 in the form of a tape.

The light emitting diode module 30 is mounted on the inner end surface of the heat sink 10 with a heat adhesive, which serves as an insulating material for insulating the heat sink 10 and the light emitting diode and a conductor for facilitating heat transfer. do.

The reflecting plate 10a is to reflect the light emitted from the light emitting diode 52. The reflecting plate 10a is coupled to maintain an angle on the inner inclined surface of the heat sink 10.

The connection part 70 of the present invention is composed of a pair of spring fixing bracket as shown in Figure 4 and 5 and is inserted and fixed using the retaining tension to the upper surface groove of the heat sink 10, which is a conventional fluorescent light fixture When removing and installing the luminaire of the present invention, it provides a feature that allows for easy installation regardless of the deviation of the unstandardized screw holes.

The present invention described above, by using a plurality of high-brightness light emitting diodes to achieve a brightness efficiency of 110% or more with about one-sixth of the power of a conventional fluorescent lamp, minimizing power consumption as shown in Table 1, The service life of a minimum of 30,000 hours and a maximum of 35,000 hours is maximized.

In addition, according to the present invention, the brightness of the light emitting diode is adjusted by pre-sensing by the sensor module 60, so that the user who actually passes the lower part of the luminaire does not recognize the change in the lighting, and the CCTV light is in the standby time when the change is not detected at the bottom. In order to maintain only the minimum brightness required, compared to the prior art due to the difference in the driving state, it can be seen that the total power used is as shown in Table 1, thereby greatly reducing the power consumption.

Maximum brightness operation Power Consumption Minimum brightness operation Power Consumption Power total Existing Consumption Saving rate 8 hours 144 W 16 hours 80 W 224 W 768 W 70.8% 6 hours 108 W 18 hours 90 W 198 W 768 W 74.2% 4 hours 72 W 20 hours 100 W 172 W 768 W 77.6% 2 hours 36 W 22 hours 110 W 146 W 768 W 81.0% * Power consumption of existing fluorescent lamps: 32W / h
* Our luminaire power consumption: max.mode 18W / h standby mode 5W / h

In addition, the present invention realizes optimization of heat treatment because the heat is maintained at 50 or less when the light-emitting diode is turned on in a room temperature of 25 degrees Celsius, no ventilation, no heat sink conditions, and the voltage used in the luminaire is not limited, so Can be used.

On the other hand, the present invention solves the problem of maintenance and safety management can not know the remaining life in the case of the existing fluorescent lamp, so that it is possible to know in advance the replacement time through the life indicator, to the maximum brightness and minimum brightness It eliminates the lighting gap that can occur when switching, and is designed to enter in a situation where an approach object, especially a high-speed object such as a vehicle, is always illuminated brightly when approaching, thereby enhancing user safety.

In addition, the present invention is provided with a fixing subsidiary material that is movable to overcome the different mounting conditions that may occur during the replacement operation of the existing luminaires, to prevent the case of failing to attach due to the different fixing screw holes. In addition, it is easy to attach and detach by fixing using spring tension.

It will be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof.

Therefore, the present invention is not limited to the above-described embodiments, and various changes can be made by any person having ordinary skill in the art without departing from the gist of the present invention as claimed in the following claims. It will be said that the technical spirit of this invention is to the extent possible.

10: heat sink 20: PC cover
30: light emitting diode module 40: circuit housing
40a: printed circuit board 40b: SMPS
40c: bushing 40d: through hole
50: indicator
50a: indicator printed circuit board 50b: LED life display
60: sensor module
60a: printed circuit board 60b: sensor
60c: Sensor Lens
70: connection

Claims (3)

delete A printed circuit board on which a light emitting diode driving circuit and a switch mode power supply (SMPS) are formed;
A circuit housing having a through hole connecting the SMPS to an AC power input system while accommodating the printed circuit board;
Heat dissipation is formed in the straight metal plate for the heat dissipation, the circuit housing is coupled to the upper center;
A light emitting diode module in which a light emitting diode controlled by the light emitting diode driving circuit is linearly disposed on a straight substrate that is heat bonded to the inside of the heat sink;
A straight reflection plate coupled to both inner end surfaces of the lower end of the heat sink to maintain a predetermined reflection angle in a side direction;
A PC cover coupled to a lower end of the heat sink to protect and protect the light emitting diode module and the linear reflecting plate, prevent glare, and diffuse light;
A sensor module composed of an infrared sensor embedded in a sensor case coupled to one side of the heat sink and a sensor lens for condensing a lower infrared signal with an infrared sensor to detect a movement of an object at the bottom and to send a signal to a power supply unit;
A life display indicator unit configured to display an LED lifetime of the light emitting diode module by forming a life detection circuit of the light emitting diode and an LED life display unit on an indicator circuit board embedded in an indicator case coupled to the other side of the heat sink;
Is coupled to the top of the heat sink is coupled to the spring tension to attach the entire device to the fixed structure; consisting of,
The sensor module adjusts the infrared detection angle toward the front of the luminaire so as to pre-detect the object approaching the bottom of the luminaire,
The LED driving circuit may be configured to illuminate the LED at maximum brightness in advance according to a detection signal of the sensor module, and to maintain the maximum brightness for a set time after the object passes and to be switched to the minimum brightness. . A printed circuit board on which a light emitting diode driving circuit and a switch mode power supply (SMPS) are formed;
A circuit housing having a through hole connecting the SMPS to an AC power input system while accommodating the printed circuit board;
Heat dissipation is formed in the straight metal plate for the heat dissipation, the circuit housing is coupled to the upper center;
A light emitting diode module in which a light emitting diode controlled by the light emitting diode driving circuit is linearly disposed on a straight substrate that is heat bonded to the inside of the heat sink;
A straight reflection plate coupled to both inner end surfaces of the lower end of the heat sink to maintain a predetermined reflection angle in a side direction;
A PC cover coupled to a lower end of the heat sink to protect and protect the light emitting diode module and the linear reflecting plate, prevent glare, and diffuse light;
A sensor module composed of an infrared sensor embedded in a sensor case coupled to one side of the heat sink and a sensor lens for condensing a lower infrared signal with an infrared sensor to detect a movement of an object at the bottom and to send a signal to a power supply unit;
A life display indicator unit configured to display an LED lifetime of the light emitting diode module by forming a life detection circuit of the light emitting diode and an LED life display unit on an indicator circuit board embedded in an indicator case coupled to the other side of the heat sink;
Is coupled to the top of the heat sink is coupled to the spring tension to attach the entire device to the fixed structure; consisting of,
The life detection circuit of the life indicator indicator unit
In real-time cumulative calculation of the maximum output driving time of the light emitting diode,
The LED lifetime display unit is composed of green, red, sulfur LEDs, ultra-low power LED fixed luminaires, characterized in that it is possible to know the available time and replacement time of the luminaire by displaying the color classification according to the life state.

Images