KR101256482B1 - Individual control system of electric light - Google Patents

Abstract

PURPOSE: An individual control system of a lamp unit is provided to prevent generation of malfunction caused by interference of an infrared signal, thereby individually controlling the lamp unit. CONSTITUTION: An infrared receiving module(150) includes an infrared sensing sensor and an infrared lens. The infrared sensing sensor receives an infrared signal which is transmitted from a remote controller. The infrared lens limits a receiving range of the infrared signal which is received from the infrared sensing sensor. The infrared lens includes a blocking cover and a diffusion lens. The diffusion lens diffuses the infrared signal which is received through an infrared receiving ball. The diffusion lens provides the diffused infrared signal to the infrared sensing sensor.

Description

Individual control system of electric light unit

The present invention relates to an individual control system of a light unit that can individually control a plurality of light units installed in a railway vehicle, railway station, building, and the like with a remote control.

In general, railroad cars, buildings, and history are equipped with lights to illuminate the darkness.

Such a lamp is formed on a ceiling in a form in which a plurality of light units are arranged in a line or in a variety of forms by forming a light unit in a form in which one or two fluorescent lamps are provided in one reflection shade.

On the other hand, in order to turn on (ON) or off (OFF) the light unit to operate the switch individually connected to each light unit, or to operate a switch that can control all the light unit as a whole.

However, since there are a large number of light units installed in a history or a building, to control these light units, not only the switch must be moved to the position where the switch is located, but also the position of the switch varies depending on the connected wiring. Difficult to find the location of the switch was a problem.

In order to solve this problem, conventionally, "LED lighting apparatus using a remote control" of Korean Patent Registration No. 10-1026461 has been disclosed.

Conventional LED lighting device using a remote control is an LED lighting device that can replace the light that illuminates the interior of the home or office space, and receives an infrared light selection signal for on / off lighting and brightness control of the LED light from the remote control An infrared receiver; A control circuit unit for outputting a corresponding illumination driving control signal according to an illumination selection signal of infrared rays inputted from the infrared receiver; A switching mode power supply unit (SMPS) for supplying driving power of a corresponding LED light according to an illumination driving control signal of the control circuit unit; A plurality of LED modules in which on / off lighting and brightness are controlled by power applied from the switching mode power supply unit; A diffusion film for diffusing light emitted from the plurality of LEDs as the LED module is turned on; And a glove for preventing glare of light emitted from the plurality of LEDs, wherein the remote controller includes a plurality of control channels, and the plurality of LED modules are assigned control channels of the remote controller. The lighting and brightness are controlled according to the command of the illumination selection signal of the infrared light through the control channel.

LED lighting device using a conventional remote control having the above-described configuration is inconvenient to find a switch to control the LED light, or to move to the place where the switch is installed because the user can easily operate the LED light using the remote control Could resolve.

However, since the conventional LED lighting device uses a remote control channel to control the LED light, the remote controller for generating an infrared signal required for allocating the control channel from the LED module must be manufactured separately. In order to perform different operations according to the LED module has a complex design, high manufacturing costs were a problem.

In addition, the conventional LED lighting device using a remote control has a problem that the LED lighting device due to the interference of the infrared signal malfunctions as well as the LED module for controlling the infrared signal generated from the remote control, the adjacent LED module.

In addition, the conventional LED lighting device using a remote control has a problem that it is difficult to install in a conventionally installed light unit, the LED light is modularized.

The present invention is to solve the problems as described above, the problem to be solved by the present invention is to prevent the occurrence of malfunction due to the interference of the infrared signal to easily control the light unit individually, the existing installed light Not only can be easily applied to the unit, but also provides a separate control system of the light unit that can be easily installed, the structure is simple to reduce the manufacturing cost and installation cost.

The individual control system of the light unit according to an embodiment of the present invention for achieving the above object is at least one lamp, a power supply module for supplying power to the lamp and the power supply from the power supply module to the lamp or A plurality of light units including an infrared receiving module to block is installed, the individual control system of the light unit to individually control each light unit through a remote control for sending infrared signals to the infrared receiving module, the infrared receiving module Infrared detection sensor for receiving an infrared signal transmitted from the remote control, and an infrared lens for limiting the reception range of the infrared signal received by the infrared sensor, the infrared lens is an infrared signal transmitted from the remote control Infrared Difference with Infrared Receivers Cover, and it is located in the interior of the infrared cut cover diffuse infrared signals flowing through the infrared singong may include a diffusion lens provided in the infrared sensor.

The diffusion lens may include a diffusion part which is concave at a position corresponding to the infrared reception hole to diffuse an infrared signal to the infrared detection sensor.

The infrared blocking cover may include a plurality of elastic hooks protruding radially outwardly of the infrared blocking cover to fix the infrared receiving module.

The diffusion lens includes a plurality of coupling protrusions protruding to the outside of the diffusion lens, and the infrared cut-off cover includes a protrusion groove into which the coupling protrusion is inserted and fixed, so that the coupling protrusion is fitted into the protrusion groove. The diffusion lens and the infrared ray shield cover may be coupled to each other.

The infrared blocking cover may be formed by injection molding a material that blocks infrared rays or by applying a material that blocks infrared rays.

The infrared receiving module includes a control unit for supplying or cutting off power to the power supply module according to the infrared signal received from the infrared sensor, and a memory unit for storing a state in which the control unit last controlled the power supply module. Can be.

The infrared receiving module may include a case surrounding the infrared receiving module to prevent the inflow of foreign matter.

It may include a main switch for entirely blocking or supplying power supplied to the plurality of light units.

The individual control system of the light unit according to the present invention, the infrared lens is configured to limit the reception range of the infrared signal can prevent malfunction due to the interference of the infrared signal transmitted from the remote control, and the individual control of the plurality of light units It is possible.

In addition, the manufacturing cost can be reduced by a relatively simple structure, it can be easily applied to the existing light unit installed.

In addition, a diffusion lens may be installed to increase the reception rate of the infrared signal.

In addition, the combination of the elastic hook is not only easy to install, but also provided with a memory unit can maintain the final control state of the light unit even if the power is re-supplied after the power is cut off by the main switch.

1 is a perspective view showing an individual control system of a light unit according to an embodiment of the present invention.
2 is a schematic configuration diagram of an individual control system of a light unit according to an exemplary embodiment of the present invention.
3 is a schematic configuration diagram of an infrared light receiving module constituting an individual control system of a light unit according to an exemplary embodiment of the present invention.
4 is a perspective view showing a state in which the infrared lens of the infrared receiving module constituting the individual control system of the light unit according to an embodiment of the present invention installed in the light unit.
Figure 5 is a side cross-sectional view of the infrared receiving module constituting the individual control system of the light unit according to an embodiment of the present invention installed in the light unit.

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

As shown in Figure 1 and 2, the individual control system 100 of the light unit according to an embodiment of the present invention may include a light unit (110).

The light unit 110 may irradiate light to illuminate a dark place. On the other hand, the light unit 110 may be provided on the ceiling, the plurality of light units 110 may be installed side by side or arranged in a state spaced apart from each other.

On the other hand, the light unit 110 may include a lamp (120). The lamp 120 is to irradiate light, it may be implemented as a fluorescent lamp or LED.

In addition, a plurality of lamps 120 may be installed in one lamp unit 110.

The light unit 110 may include a reflector plate 130. The reflector 130 may reflect the light of the lamp 120 to improve the efficiency of the light emitted from the lamp 120.

One or more lamps 120 may be installed in the reflector plate 130, and one light unit 110 is generally composed of one reflector plate 130 and the number of light unit 110 through the number of reflector plates 130. Can be identified.

In addition, the reflector plate 130 may be formed in a shape that is bent in an optimal shape for reflecting light, and the reflector plate 130 is installed so that the infrared lens 160 of the infrared receiver module 150 to be described below is exposed. The lens installation hole 131 may be formed.

The light unit 110 may include a power supply module 180. The power supply module 180 may convert the power supplied from the outside into the lamp 120 to be supplied to the lamp 120.

On the other hand, the power supply module 180 may be implemented as a SMPS (Swinching Mode Power Supply) or a ballast or adapter (adapter) to convert the current and voltage suitable for the lamp 120 supplied from the outside.

At this time, the power supply module 180 may be configured in the form of a combination of SMPS or ballast or adapter.

In addition, the light unit 110 may be provided with a plurality of lamps 120 in one power supply module 180, the number of the light unit 110 is identified by the same number as the number of power supply module 180. Can be.

As shown in FIG. 3, the light unit 110 may include an infrared light receiving module 150. The infrared light receiving module 150 receives the infrared signal generated from the outside and supplies or cuts off the power supplied from the power supply module 180 to the lamp 120 according to the received infrared signal, that is, the lamp 120 is turned on ( ON) or OFF.

In addition, the infrared reception module 150 may include an infrared detection sensor 173. The infrared sensor 173 may detect the infrared signal and provide the detected information to the controller 170 to be described below.

Here, since the infrared sensor 173 is a known technique, detailed description thereof will be omitted.

As shown in FIG. 4 and FIG. 5, the infrared receiving module 150 may include an infrared lens 160. The infrared lens 160 receives the reception range a of the infrared sensor 173 that receives the infrared signal so that the infrared sensor 173 can detect only the infrared signal generated within the reception range having an arbitrary angle. You can limit it.

Meanwhile, the infrared lens 160 may include an infrared blocking cover 161. The infrared cut-off cover 161 passes only the infrared signal generated in the limited reception range (a) to provide to the infrared detection sensor 173, and can block the infrared signal generated outside the reception range (a).

That is, the infrared ray blocking cover 161 acts on both the infrared receiving module 150 and the adjacent infrared receiving module 150 for controlling the infrared signal generated from the remote controller 190 to prevent the occurrence of malfunction due to the interference of the infrared signal. can do.

In addition, the infrared cutoff cover 161 may be formed in a convex hemispherical shape, and may be formed in the center portion of the infrared cutoff cover 161 through the infrared light receiving hole 162.

The infrared light receiving hole 162 is a portion through which the infrared signal passes through the infrared blocking cover 161, and may set a reception range (a) of the infrared signal according to the size of the infrared light receiving hole 162.

For example, as the size of the infrared receiver 162 increases, the receiving range a of the infrared signal becomes wider. On the contrary, as the size of the infrared receiver 162 decreases, the receiving range a of the infrared signal narrows. The size of the infrared receiver 162 may be set.

In the embodiment, the size of the infrared receiver 162 is formed such that the infrared lens 160 can receive only the infrared signal transmitted within an angle of 5 ° to 10 °.

On the other hand, the infrared blocking cover 161 is formed in a shape that is injection molded with a known material that can block infrared rays, or applied to the inner or outer surface, or both inside and outside surfaces of the infrared blocking cover 161 with a material that can block infrared rays. It may be configured in the form.

In addition, the infrared ray shield cover 161 may include an elastic hook 163. The elastic hook 163 may couple the infrared receiving module 150 to the light unit 110.

At this time, the infrared receiving module 150 may be installed in the state in which the infrared receiving hole 162 of the infrared cut-off cover 161 is exposed to the outside in the infrared module installation hole formed in the reflecting plate 130, the elastic hook 163 The infrared receiving module 150 may be coupled to the reflector plate 130 in a form that spans the circumference of the infrared module installation hole.

On the other hand, the plurality of elastic hooks 163 may be formed to protrude outward from the upper periphery of the infrared cut cover 161. In this case, the elastic hook 163 may be configured to return to the initial position when the pressing force is released in a state in which the elastic hook 163 is pressed inwardly due to the elastic force.

In addition, a projection groove 164 may be formed in the infrared ray blocking cover 161. The protrusion grooves 164 are grooves for coupling the diffusion lens 165 to be described below, and a plurality of protrusion grooves 164 may be formed on the inner circumferential surface of the infrared ray shield cover 161.

The infrared lens 160 may include a diffusion lens 165. The diffusion lens 165 may diffuse the infrared signal introduced through the infrared light receiving hole 162 formed in the infrared blocking cover 161 to provide the infrared detection sensor 173.

Meanwhile, the diffusion lens 165 may be formed in a hemispherical shape having the same outer circumferential surface as the inner circumferential surface of the infrared ray blocking cover 161 to be coupled to the inner circumferential surface of the infrared ray blocking cover 161 in contact with each other.

The diffusion lens 165 may be formed of a transparent body, and a plurality of coupling protrusions 167 protruding outward may be formed around the upper end of the diffusion lens 165.

The coupling protrusion 167 may be coupled to the projection blocking groove 164 formed on the inner circumferential surface of the infrared blocking cover 161 so that the infrared blocking cover 161 and the diffusion lens 165 may be coupled to each other. At this time, the projection groove 164 formed in the infrared blocking cover 161 is of course formed at the position of the inner peripheral surface of the infrared blocking cover 161 corresponding to the coupling projection 167 of the diffusion lens 165.

The diffuser lens 165 may include a diffuser 166. The diffusion unit 166 may be formed in a concave shape in a direction in which the infrared signal is received, and may diffuse the infrared signal introduced into the infrared module through the infrared receiver 162 to transmit the infrared signal to the infrared sensor 173.

In this case, the diffusion unit 166 may be formed at a position corresponding to the infrared light receiving hole 162 while the infrared blocking cover 161 and the diffusion lens 165 are coupled, and the infrared detection sensor 173 is a diffusion lens. Naturally located in the direction opposite to the infrared receiver 162 around the center (165).

Since the diffuser 166 configured as described above diffuses the infrared signal received through the infrared receiver 162 having a relatively small size through the diffuser 166, a small amount of the infrared signal is received by the infrared receiver 162. Even if it is introduced through), the infrared sensor 173 can improve the reception rate of the infrared signal by having an effect as if a large amount of infrared signals are introduced.

The infrared ray receiving module 150 may include a controller 170. The controller 170 may turn on or off the lamp 120 in a form of supplying or blocking power supplied from the outside to the power supply module 180 based on the infrared signal received from the infrared sensor 173. .

In addition, the infrared receiver module 150 may include a memory unit 175. The memory unit 175 may store a state in which the control unit 170 finally controls the power supply module 180, that is, a state in which the power supply module 180 is operated to supply or cut off power.

For example, when the supply of power to the power supply module 180 is cut off and the lamp 120 is turned off, the memory unit 175 lastly cuts off the power supplied from the outside to the light unit 110. Even when supplied again, the power supplied to the power supply module 180 may be cut off to maintain the state in which the lamp 120 is turned off.

On the other hand, the infrared sensor 173, the control unit 170, the memory unit 175 constituting the infrared receiving module 150 may be configured on a single PCB substrate 171 as semiconductor elements electrically connected to each other. .

The infrared reception module 150 may include a case (not shown). Although not shown in the drawing, the infrared receiving module 150 is positioned in the state in which only the infrared lens 160 is exposed to the outside, and the rest of the configuration, for example, the infrared sensor 173, all of the control unit, and the memory unit 175. The back may be enclosed in a wrapping form so that the infrared light receiving module 150 is separately installed from the light unit 110.

At this time, the infrared receiving module 150 is naturally connected to the power supply module 180 and each other.

The individual control system 100 of the light unit according to the embodiment of the present invention may include a main switch 185.

The main switch 185 is a plurality of light units 110 are electrically connected to each other, the power supply to the entire plurality of light units 110 in the form of cutting off or supplying power to the plurality of light units 110. Can be supplied or shut off.

In this case, the main switch 185 may be implemented as a known electronic switch or a manual operation switch or a circuit breaker in which the power supply drawing is arbitrarily set.

The individual control system 100 of the light unit according to the embodiment of the present invention may include a remote controller 190.

The remote controller 190 may transmit an infrared signal that can be received and communicated by the infrared receiving module 150, and a plurality of buttons are provided to transmit different infrared signals according to the buttons.

For example, the remote controller 190 includes an on button and an off button to generate different infrared signals when each button is pressed, and the infrared signal is received by the infrared receiving module 150 and supplied to the power supply module 180. Can be powered on or off.

Here, since the configuration of the remote controller 190 for transmitting infrared rays is a known technology, further detailed description thereof will be omitted.

The operation and effect between the above-described respective constitutions will be described.

In the individual control system 100 of the light unit according to the embodiment of the present invention, first, the light unit 110 is installed at least one lamp 120 under the reflecting plate 130, the lamp 120 is from the outside The power supply module 180 is electrically connected to each other to receive and convert power, and the power supply module 180 is configured to be electrically connected to the infrared receiving module 150.

At this time, the infrared receiving module 150 may be installed separately from the light unit 110 in a form wrapped around the case, the infrared receiving module 150, as in the embodiment, the elastic hook 163 of the infrared lens 160 ) Is installed in such a way as to span the lens installation hole 131 formed in the reflecting plate 130. In addition, an electric lamp having a PCB substrate 171 including an infrared sensor 173, a controller 170, and a memory unit 175 is installed in a direction opposite to the reflective plate 130 on which the infrared lens 160 is installed. May be coupled to the unit 110.

On the other hand, the light unit 110 configured as described above may be provided in the ceiling 200 in a plurality of forms arranged in parallel with each other or arranged in various forms.

Here, the plurality of light units 110 may be configured to be electrically connected to each other to one power supplied from the outside, the main switch 185 is provided in the power to which the plurality of light units 110 are connected to the main switch 185 may be configured to supply or cut off power to the plurality of light units 110.

The individual control system 100 of the light unit configured as described above, first, the main switch 185 is turned on to supply power to the plurality of light units 110.

In this state, the user moves to the light unit 110 to turn on or off the light 120 among the plurality of light units 110 while carrying the remote controller 190 to receive infrared rays provided in the light unit 110. The module 150, more specifically, the infrared sensor 173, operates the remote controller 190 within the reception range a in which the infrared signal can be detected.

On the other hand, the infrared signal transmitted from the remote control 190 is received by the infrared sensor 173 through the infrared lens 160, the infrared sensor 173 provides the detected information of the infrared to the controller 170 to control the controller. By determining the information detected by the 170, the lamp 120 may be turned on or off in a form of supplying or blocking power to the power supply module 180.

At this time, the infrared lens 160 provided in the light unit 110 is configured to receive an infrared signal only through the infrared light receiving hole 162 of the infrared blocking cover 161 to limit the receiving range that can receive the infrared signal. Therefore, except for the infrared light receiving module 150 located within the receiving range (a) to be adjusted by the remote control 190, the infrared light receiving module 150 provided in the remaining light unit 110, the infrared rays sent from the remote control 190 Since no signal is received, malfunctions due to interference of infrared signals can be prevented.

In addition, when controlling all the light unit 110, the main switch 185 is used to control the form of shutting off or supplying the entire power.

At this time, since the infrared receiving module 150 stores the last operating state of the infrared receiving module 150 including the memory unit 175, even if the power is cut off using the main switch 185 and the power is supplied again. The state of the power unit 110 may be maintained before the power supply is cut off.

For example, when the power is cut off by the main switch 185 in a state in which the lighting unit 120 of one of the light units 110 is controlled by the remote controller 190, the memory unit 175 is the light unit 110. Even when the power is supplied again through the main switch 185 by remembering the last controlled state, the lamp 120 of the corresponding light unit 110 may be kept in the off state without being turned on again.

Therefore, since the individual control system 100 of the light unit according to the embodiment of the present invention can be controlled to individually control the light unit 110 in a relatively simple configuration, it is possible to reduce the system installation cost for individual control By controlling the light unit 110 efficiently, power saving efficiency can be improved.

In addition, it can be made of a relatively simple configuration to reduce the manufacturing cost, it can be easily applied to the existing light unit.

In addition, the plurality of light units 110 may be easily controlled individually by preventing interference of infrared signals generated by the remote controller 190.

In addition, the elastic hook 163 may be provided to easily couple the infrared light receiving module 150 to the light unit 110.

In addition, the memory unit 175 may be provided to maintain a finally controlled state of the light unit 110.

In addition, the diffusion lens 165 may be installed to improve the reception rate of the infrared signal.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100: individual control system of the light unit 110: light unit
120: light 130: reflector
131: lens installation 150: infrared receiving module
160: infrared lens 161: infrared cut cover
162: infrared receiver 163: elastic hook
164: projection groove 165: diffused lens
166: diffusion portion 167: engaging projection
170: control unit 171: PCB substrate
173: infrared sensor 175: memory unit
180: power supply module 185: main switch
190: remote control 200: ceiling

Claims (8)

A plurality of light units including at least one lamp, a power supply module for supplying power to the lamp, and an infrared light receiving module for supplying or cutting off power from the power supply module to the lamp, are installed to the infrared receiving module As a separate control system of a light unit for controlling each light unit individually through a remote control that sends an infrared signal,
The infrared receiving module includes an infrared sensor for receiving an infrared signal transmitted from the remote control, and an infrared lens for limiting the reception range of the infrared signal received by the infrared sensor,
The infrared lens has an infrared ray blocking cover formed with an infrared ray receiving hole for passing an infrared signal transmitted from the remote control only within an arbitrary reception range, and is positioned inside the infrared ray blocking cover to spread the infrared signal flowing through the infrared ray receiving hole. It includes a diffusion lens provided to the infrared sensor,
The diffusion lens includes a diffusion portion which is formed concave at a position corresponding to the infrared reception hole to diffuse an infrared signal into the infrared detection sensor,
The infrared blocking cover includes a plurality of elastic hooks protruding radially outwardly of the infrared blocking cover to fix the infrared receiving module.
The diffusion lens includes a plurality of coupling protrusions protruding to the outside of the diffusion lens, and the infrared cut-off cover includes a protrusion groove into which the coupling protrusion is inserted and fixed, so that the coupling protrusion is fitted into the protrusion groove. The diffusion lens and the infrared ray shield cover are coupled to each other,
The infrared receiving module includes a control unit for supplying or cutting off power to the power supply module according to the infrared signal received from the infrared sensor, and a memory unit for storing a state in which the control unit last controlled the power supply module. ,
Individual control system of a light unit comprising a main switch for totally cutting off or supplying the power supplied to the plurality of light units. delete delete delete The method of claim 1,
The infrared blocking cover
Individual control system of the light unit, characterized in that the injection molding of the material blocking the infrared ray or the material blocking the infrared ray is applied. delete The method of claim 1,
The infrared receiving module
Individual control system of the light unit, characterized in that it comprises a case surrounding the infrared receiving module to prevent the inflow of foreign matter. delete

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