KR20130039934A - Illuminator for emergency - Google Patents

Abstract

PURPOSE: An emergency lighting device is provided to rapidly notify an emergency situation by automatically or manually emitting only the red light in an emergency situation. CONSTITUTION: A plurality of light emitting diode packages(DP) emit white light. A plurality of emergency red light emitting diode chips(RD) emit red light. A driving power generating unit(DPGB) generates driving power by receiving external power. A sub power generating and accumulating unit(APGB) generates and accumulates sub driving power by receiving the external power. A power block monitoring unit(PCMB) outputs a blocking signal(BS) when the power is cut off. [Reference numerals] (APGB) Sub power generating and accumulating unit; (DPGB) Driving power generating unit; (LSDB) Light source driving unit; (PCMB) Power block monitoring unit;

Description

Emergency lighting equipment {ILLUMINATOR FOR EMERGENCY}

The present invention relates to a lighting device, and in particular, to emit a general white light in ordinary times, to an emergency lighting device that can quickly propagate an emergency situation by emitting only a red light in an emergency.

Conventional lighting equipment is not suitable for military units, fire departments, theaters, emergency centers, disaster-related government offices, etc., which are required to quickly propagate emergency situations due to the emission of general white light.

The present invention is conceived in consideration of the conventional situation as described above, the normal white light is usually used as a general lighting, the emergency, which can be quickly switched to an emergency light that emits only red light automatically or manually in an emergency The purpose is to provide a lighting device.

Emergency lighting device according to the present invention for achieving the above object, a plurality of light emitting diode packages for emitting white light; A plurality of emergency red light emitting diode chips emitting red light; A driving power generation unit configured to generate driving power by receiving external power; An auxiliary power generation / accumulator configured to generate and accumulate auxiliary driving power by receiving the external power; A power cut-off monitoring unit that monitors whether the external power is cut off and outputs a cutoff signal when the power is cut off; And a light source driver configured to supply the auxiliary driving power to the at least one red light emitting diode chip from the auxiliary power generation / accumulator in response to the blocking signal from the power cutoff monitoring unit.

When there is no blocking signal from the power cut-off monitoring unit, the light source driving unit supplies driving power from the driving power generating unit to the plurality of light emitting diode packages; In addition, there is no blocking signal from the power cut-off monitoring unit, and when a forced emergency signal is input from the outside, the light source driving unit supplies driving power from the driving power generating unit to the plurality of emergency red LED chips. It is characterized by.

A printed circuit board on which the light emitting diode packages and the emergency red light emitting diode chips are mounted; And a protective cover surrounding the printed circuit board.

The number of light emitting diode packages is greater than or equal to the number of non-commercial red light emitting diode chips.

The plurality of light emitting diode packages are arranged in a row on the printed circuit board; A plurality of emergency red light emitting diode chips are arranged in a row on the printed circuit board; The non-commercial red light emitting diode chips are arranged in a line between the light emitting diode packages arranged in a row along one row and the light emitting diode packages arranged in a row along another row adjacent thereto.

When the auxiliary driving power or the driving power is supplied to the at least one emergency red light emitting diode chip, the light source driver supplies the auxiliary driving power or the driving power to all the emergency red light emitting diode chips.

When the auxiliary driving power source or the driving power is supplied to the at least one emergency red light emitting diode chip, the light source driving unit causes the light emitting emergency red light emitting diode chips to display any one of specific letters, numbers, and arrows. Alternatively, the driving power may be selectively supplied to specific emergency red light emitting diode chips.

Each light emitting diode package is characterized by including a red light emitting diode chip, a green light emitting diode chip and a blue light emitting diode chip therein.

In addition, another emergency lighting device according to the present invention for achieving the above object, a plurality of light emitting diode package including a red light emitting diode chip, a green light emitting diode chip and a blue light emitting diode chip therein; A driving power generation unit configured to generate driving power by receiving external power; An auxiliary power generation / accumulator configured to generate and accumulate auxiliary driving power by receiving the external power; A power cut-off monitoring unit that monitors whether the external power is cut off and outputs a cutoff signal when the power is cut off; And a light source driver configured to supply the auxiliary driving power to the at least one red light emitting diode chip from the auxiliary power generation / accumulator in response to the blocking signal from the power cutoff monitoring unit.

When there is no blocking signal from the power cut-off monitoring unit, the light source driving unit supplies driving power from the driving power generating unit to the red light emitting diodes, the green light emitting diodes, and the blue light emitting diodes provided in the plurality of light emitting diode packages. To; In addition, there is no blocking signal from the power cut-off monitoring unit, and when a forced emergency signal is input from the outside, the light source driving unit supplies driving power from the driving power generating unit to at least one red light emitting diode chip. It is done.

A printed circuit board on which the plurality of light emitting diode packages are mounted; And a protective cover surrounding the printed circuit board.

n light emitting diode packages (n being a natural number greater than 1) are arranged on the printed circuit board in an i * j matrix (i * j = n).

When the auxiliary driving power or the driving power is supplied to the at least one red light emitting diode chip, the light source driver selectively supplies the auxiliary driving power to the red light emitting diode chips in the light emitting diode packages located in even-numbered rows.

When the auxiliary driving power or the driving power is supplied to the at least one red light emitting diode chip, the light source driver specifies the auxiliary driving power so that the light emitting red light emitting diode chips display any one of a specific letter, number, and arrow. It is characterized in that the selective supply to the red light emitting diode chip.

Emergency lighting equipment according to the present invention provides the following effects.

The emergency lighting device according to the present invention emits white light in normal times, but can quickly notify an emergency situation by emitting red light automatically or manually in an emergency. For example, the emergency lighting device according to the present invention can be used where military conditions, fire departments, theaters, emergency centers, disaster-related public offices, etc. need a quick situation in the event of emergency.

In addition, the emergency lighting device according to the present invention can accurately indicate the location of the shelter or exit by flashing the red light in an emergency or by displaying the red light in the form of a specific letter or symbol (for example, an arrow pointing in a specific direction). .

1 is a view showing an emergency lighting device according to a first embodiment of the present invention
2 is a view showing the configuration of the lighting unit shown in FIG.
3A is a view illustrating a state in which only light emitting diode packages provided in the lighting unit of FIG. 2 are selectively lit;
3B is a view illustrating a state in which only emergency red light emitting diode chips provided in the lighting unit of FIG. 2 are selectively lit;
3C is a view illustrating a state in which only some of the emergency red light emitting diode chips included in the lighting unit of FIG. 2 are selectively lit.
4 is a view showing an emergency lighting device according to a second embodiment of the present invention;
5 is a view showing the configuration of the lighting unit shown in FIG.
6A is a view illustrating a state in which all of the light emitting diode packages included in the lighting unit of FIG. 5 are turned on;
6B is a view illustrating a state in which only red light emitting diode chips in each light emitting diode package included in the lighting unit of FIG. 5 are selectively lit.
FIG. 6C is a view illustrating a state in which only some of the red light emitting diode chips in each light emitting diode package included in the lighting unit of FIG. 5 are selectively lit.
FIG. 6D is a view illustrating a state in which only some of the red light emitting diode chips in each light emitting diode package included in the lighting unit of FIG. 5 are selectively lit. FIG.
7 is a view showing the shape of a printed circuit board according to an embodiment of the present invention;

1st Example

1 is a view showing an emergency lighting device according to a first embodiment of the present invention.

As shown in FIG. 1, the emergency lighting apparatus according to the first embodiment of the present invention may drive an illumination unit ILN in which a plurality of light emitting diode packages DP and a plurality of emergency red light emitting diode chips ERD are formed. A power generation unit (DPGB), an auxiliary power generation / accumulation unit (APGB), a power interruption monitoring unit (PCMB), and a light source driving unit (LSDB).

Each light emitting diode package DP includes a red light emitting diode chip RD, a green light emitting diode chip GD, and a blue light emitting diode chip BD. The red light emitting diode chip RD emits red light, the green light emitting diode chip GD emits green light, and the blue light emitting diode chip BD emits blue light. The light emitting diode package DP mixes the light from the red light emitting diode chip RD, the green light emitting diode chip GD, and the blue light emitting diode chip BD included therein to generate white light. Therefore, white light is emitted from each light emitting diode package DP.

The emergency red light emitting diode chips ERD positioned outside the light emitting diode package DP are actually the same as the red light emitting diode chip RD formed inside the light emitting diode package DP. That is, this emergency red light emitting diode chip (ERD) emits red light.

The driving power generation unit DPGB receives the external power PW, and boosts or decompresses the external power PW to generate the driving power DPS. As the driving power generation unit DPGB, a switching mode power supply may be used.

The auxiliary power generation / accumulator APGB receives the external power PW, and boosts or decompresses the external power PW to generate the auxiliary drive power ADPS. The generated auxiliary drive power supply ADPS is stored in an internal battery. The auxiliary power generation / accumulation unit (APGB) may include a switching mode power supply including a battery.

The power cutoff monitoring unit (PCMB) monitors whether the external power (PW) is cut off, and outputs a cutoff signal (BS) when the external power (PW) is cut off. That is, the power interruption monitoring unit PCMB continuously monitors the size of the external power PW in real time from the moment when the external power PW is input to the lighting device. When the external power PW input to the lighting device is abnormally cut off and the external power PW falls below a preset size, a block signal BS is generated. For example, when the level of the external power PW input to the luminaire quickly reaches a preset magnitude (voltage magnitude: for example, a voltage of 0 [V]) within a preset time, the power shutdown monitoring The part PCMB determines that the external power PW is abnormally cut off and outputs the cutoff signal BS described above. On the other hand, when the external power PW normally reaches the preset size beyond the preset time, the power cut-off monitoring unit PCMB indicates that the external power PW is normally shut off through a normal procedure. It judges and does not output the cutoff signal BS.

The light source driver LSDB operates differently as follows when there is no cutoff signal BS from the power cutoff monitor PCMB, when there is a cutoff signal BS, and when there is a forced emergency signal FES from the outside. do.

First, when there is no cut-off signal BS from the above-described power cut-off monitoring unit PCMB and no forced emergency signal FES from the outside, the light source driver LSDB is driven from the drive power generation unit DPGB. The power supply DPS is supplied to all the light emitting diode packages DP. Accordingly, the driving power source DPS is supplied to the red light emitting diode chip RD, the green light emitting diode chip GD, and the blue light emitting diode chip BD in all the light emitting diode packages DP. According to the driving power source DPS, the red light emitting diode chip RD emits red light, the green light emitting diode chip GD emits green light, and the blue light emitting diode chip BD emits blue light. . Therefore, white light is emitted from the lighting unit ILN when there is no blocking signal BS and forced emergency signal FES. At this time, the auxiliary power generation / accumulating unit (APGB) generates the auxiliary driving power (ADPS) using the external power (PW), and charges the internal battery.

On the other hand, when the above-mentioned power cut-off monitoring unit PCMB rotor cutoff signal BS is input to the light source driver LSDB, the light source driver LSDB is the auxiliary drive power ADPS from the auxiliary power generation / accumulation unit APGB. ) Is supplied to the emergency red light emitting diode chips (ERD). That is, the presence of the blocking signal BS means that the external power PW is not input to the lighting device. In other words, the driving power generation unit DPGB may no longer generate the driving power DPS. Accordingly, the light source driver LSDB drives the emergency red light emitting diode chips ERD using the auxiliary drive power ADPS charged in the auxiliary power generation / accumulation part APGB instead of the driving power generation unit DPGB. Therefore, when the blocking signal BS is present, red light is emitted from the lighting unit ILN. When the blocking signal BS is present, the emergency red light emitting diode chips ERD emit light by the auxiliary driving power supply ADPS from the auxiliary power generation / accumulation unit regardless of the forced emergency signal FES. do. In this case, the light source driver LSDB may drive the emergency red light emitting diode chips ERD to blink.

On the other hand, when the forced emergency signal FES is input from the outside to the light source driver LSDB, the light source driver LSDB receives the driving power DPS from the drive power generator DPGB as an emergency red light emitting diode chip ERD. To feed. Therefore, when the forced emergency signal FES is present, red light is emitted from the lighting unit ILN. In this case, the light source driver LSDB may drive the emergency red light emitting diode chips ERD to blink. On the other hand, the auxiliary power generation / accumulation unit (APGB) generates the auxiliary driving power (ADPS) by using the external power (PW), and charges the internal battery.

The forced emergency signal FES may be output through a portable remote controller. That is, the user can operate the remote controller to output the forced emergency signal FES or cancel the forced emergency situation. For example, the user may press the emergency generating key of the remote controller to supply the forced emergency signal FES to the light source driver LSDB. On the other hand, the user can release the output of the forced emergency signal FES by pressing the emergency release key of the remote control unit so that the light source driver LSDB operates normally. That is, when the output of the forced emergency signal FES is released, the light source driver LSDB drives the light emitting diode packages DP using the drive power source DPS from the drive power source generation unit DPGB. The forced emergency signal FES is input to the light source driver LSDB through the wireless antenna AT. On the other hand, the emergency lighting device according to the invention can be operated in connection with an external emergency organ. That is, the emergency signal from the external emergency engine can be transmitted to the light source driver LSDB through the wireless antenna AT. At this time, the light source driver LSDB controls the lighting unit ILN to emit red light as described above.

The light emitting diode packages DP provided in the lighting unit ILN of FIG. 1 may have the following configuration.

FIG. 2 is a diagram illustrating a configuration of the lighting unit ILN illustrated in FIG. 1.

As shown in FIG. 2, the lighting unit ILN includes a printed circuit board (PCB) on which a plurality of light emitting diode packages (DP) and emergency red light emitting diode chips (ERD) are mounted, and the printed circuit board (PCB). It is composed of a protective cover (CV) surrounding. The number of light emitting diode packages DP may be greater than or equal to the number of emergency red light emitting diode chips ERD.

A plurality of light emitting diode packages DP are arranged in a row on a printed circuit board PCB, and a plurality of red light emitting diode chips RD are also arranged in a row on a printed circuit board PCB.

In particular, the red light emitting diode chips RD are arranged in a row between the light emitting diode packages DP arranged in a row along one row and the light emitting diode packages DP arranged in a row along another row adjacent thereto. .

FIG. 3A is a view illustrating a state in which only light emitting diode packages DP provided in the lighting unit ILN of FIG. 2 are selectively lit.

That is, when there is no cutoff signal BS from the power cut-off monitoring unit PCMB and no forced emergency signal FES from the outside, the light source driving unit LSDB is the driving power source DPS from the driving power generation unit DPGB. Is supplied to all light emitting diode packages (DP). Accordingly, as shown in FIG. 3A, only white light emitted by the light emitting diode packages DP is emitted from the lighting unit ILN.

FIG. 3B is a view illustrating a state in which only emergency red light emitting diode chips ERD included in the lighting unit ILN of FIG. 2 are selectively lit.

That is, when the cutoff signal BS of the power cut-off monitoring unit PCMB is input to the light source driving unit LSDB, the light source driving unit LSDB uses the auxiliary power source ADPS from the auxiliary power generation / accumulating unit APGB as emergency red. Supply to light emitting diode chips (ERD). Accordingly, as shown in FIG. 3B, only the red light emitted by the emergency red light emitting diode chips ERD is emitted from the lighting unit ILN. At this time, according to the control of the light source driver LSDB, the emergency red light emitting diode chips ERD may blink while being turned on and off at specific cycles.

In addition, even when the forced emergency signal FES is input to the light source driver LSDB from the outside, as shown in FIG. 3B, only the red light emitted by the emergency red light emitting diode chips ERD is emitted from the illumination unit ILN. do. At this time, according to the control of the light source driver LSDB, the emergency red light emitting diode chips ERD may blink while being turned on and off at specific cycles.

FIG. 3C is a view illustrating a state in which only some of the emergency red light emitting diode chips ERD of the lighting unit ILN of FIG. 2 are selectively lit.

That is, when the cutoff signal BS or the forced emergency signal FES is input to the light source driver LSDB, as shown in FIG. 3C, the light source driver LSDB may remove some of the emergency red light emitting diode chips ERD. By selectively turning on, the lit red LED chips may display specific characters or symbols. That is, the light source driver LSDB may further include a memory, in which point / lighting information on which of the emergency red LED chips (ERD) is turned on and which is turned off is stored in advance. Therefore, the light source driver LSDB selectively lights some of the emergency red light emitting diode chips ERD based on the information stored in the memory, thereby turning on the emergency red light emitting diode chip ERD as shown in FIG. 3C. ) Can be used to display symbols such as arrows. At this time, according to the control of the light source driver LSDB, some of the emergency red light emitting diode chips ERD may blink while being turned on and off at a specific cycle.

Second Example

4 is a view showing an emergency lighting device according to a second embodiment of the present invention.

As shown in FIG. 4, the emergency lighting device according to the second embodiment of the present invention includes an illumination unit ILN, a driving power generation unit DPGB, and auxiliary power generation / accumulation, in which a plurality of light emitting diode packages DP are formed. A part (APGB), a power cut monitoring unit (PCMB) and a light source driver (LSDB).

Each light emitting diode package DP includes a red light emitting diode chip RD, a green light emitting diode chip GD, and a blue light emitting diode chip BD. The red light emitting diode chip RD emits red light, the green light emitting diode chip GD emits green light, and the blue light emitting diode chip BD emits blue light. The light emitting diode package DP mixes the light from the red light emitting diode chip RD, the green light emitting diode chip GD, and the blue light emitting diode chip BD included therein to generate white light. Therefore, white light is emitted from each light emitting diode package DP.

The driving power generation unit DPGB receives the external power PW, and boosts or decompresses the external power PW to generate the driving power DPS. As the power generation unit, a switching mode power supply may be used.

The auxiliary power generation / accumulator APGB receives the external power PW, and boosts or decompresses the external power PW to generate the auxiliary drive power ADPS. The generated auxiliary drive power supply ADPS is stored in an internal battery. The auxiliary power generation / accumulation unit (APGB) may include a switching mode power supply including a battery.

The power cutoff monitoring unit (PCMB) monitors whether the external power (PW) is cut off, and outputs a cutoff signal (BS) when the external power (PW) is cut off. That is, the power interruption monitoring unit PCMB continuously monitors the size of the external power PW in real time from the moment when the external power PW is input to the lighting device. When the external power PW input to the lighting device is abnormally cut off and the external power PW falls below a preset size, a block signal BS is generated. For example, when the level of the external power PW input to the luminaire quickly reaches a preset magnitude (voltage magnitude: for example, a voltage of 0 [V]) within a preset time, the power shutdown monitoring The part PCMB determines that the external power PW is abnormally cut off and outputs the cutoff signal BS described above. On the other hand, when the external power PW normally reaches the preset size beyond the preset time, the power cut-off monitoring unit PCMB indicates that the external power PW is normally shut off through a normal procedure. It judges and does not output the cutoff signal BS.

The light source driver LSDB operates differently as follows when there is no cutoff signal BS from the power cutoff monitor PCMB, when there is a cutoff signal BS, and when there is a forced emergency signal FES from the outside. do.

First, when there is no cut-off signal BS from the above-described power cut-off monitoring unit PCMB and no forced emergency signal FES from the outside, the light source driver LSDB is driven from the drive power generation unit DPGB. The power supply DPS is supplied to all the light emitting diode packages DP. Accordingly, the driving power source DPS is supplied to the red light emitting diode chip RD, the green light emitting diode chip GD, and the blue light emitting diode chip BD in all the light emitting diode packages DP. According to the driving power source DPS, the red light emitting diode chip RD emits red light, the green light emitting diode chip GD emits green light, and the blue light emitting diode chip BD emits blue light. . Therefore, when there is no blocking signal BS and forced emergency signal FES, the white light in which these three colors are mixed is emitted from the illumination part ILN. At this time, the auxiliary power generation / accumulating unit (APGB) generates the auxiliary driving power (ADPS) using the external power (PW), and charges the internal battery.

On the other hand, when the above-mentioned power cut-off monitoring unit PCMB rotor cutoff signal BS is input to the light source driver LSDB, the light source driver LSDB is the auxiliary drive power ADPS from the auxiliary power generation / accumulation unit APGB. ) Is supplied to the red light emitting diode chip RD in each light emitting diode package DP. That is, the presence of the blocking signal BS means that the external power PW is not input to the lighting device. In other words, the driving power generation unit DPGB may no longer generate the driving power DPS. Accordingly, the light source driver LSDB drives the red light emitting diode chips RD using the auxiliary drive power ADPS charged in the auxiliary power generation / accumulation part APGB instead of the driving power generation unit DPGB. Therefore, when the blocking signal BS is present, red light is emitted from the lighting unit ILN. When the blocking signal BS is present, the red light emitting diode chips RD are emitted by the auxiliary driving power source ADPS from the auxiliary power generation / accumulating unit APGB regardless of whether the forced emergency signal FES is present. . In this case, the light source driver LSDB may drive the red light emitting diode chips RD to blink.

On the other hand, when the forced emergency signal FES is input to the light source driver LSDB from the outside, the light source driver LSDB turns the driving power DPS from the drive power generator DPGB into red light emitting diode chips RD. To supply. Therefore, when the forced emergency signal FES is present, red light is emitted from the lighting unit ILN. In this case, the light source driver LSDB may drive the red light emitting diode chips RD to blink. On the other hand, the auxiliary power generation / accumulation unit (APGB) generates the auxiliary driving power (ADPS) by using the external power (PW), and charges the internal battery.

The forced emergency signal FES may be output through a portable remote controller. That is, the user can operate the remote controller to output the forced emergency signal FES or cancel the forced emergency situation. For example, the user may press the emergency generating key of the remote controller to supply the forced emergency signal FES to the light source driver LSDB. On the other hand, the user can release the output of the forced emergency signal FES by pressing the emergency release key of the remote control unit so that the light source driver LSDB operates normally. That is, when the output of the forced emergency signal FES is released, the light source driver LSDB drives the light emitting diode packages DP using the drive power source DPS from the drive power source generation unit DPGB. The forced emergency signal FES is input to the light source driver LSDB through the wireless antenna AT. On the other hand, the emergency lighting device according to the invention can be operated in connection with an external emergency organ. That is, the emergency signal from the external emergency engine can be transmitted to the light source driver LSDB through the wireless antenna AT. At this time, the light source driver LSDB controls the lighting unit ILN to emit red light as described above.

The light emitting diode packages DP provided in the lighting unit ILN of FIG. 4 may have the following configuration.

FIG. 5 is a diagram illustrating a configuration of the lighting unit ILN illustrated in FIG. 4.

As shown in FIG. 4, the lighting unit ILN includes a printed circuit board (PCB) on which a plurality of light emitting diode packages (DP) are mounted, and a protective cover (CV) surrounding the printed circuit board (PCB). It is composed.

In this case, a plurality of light emitting diode packages DP are arranged in a row on a printed circuit board PCB.

FIG. 6A is a view illustrating a state in which all of the light emitting diode packages DP included in the lighting unit ILN of FIG. 5 are turned on.

That is, when there is no cutoff signal BS from the power cut-off monitoring unit PCMB and no forced emergency signal FES from the outside, the light source driving unit LSDB is the driving power source DPS from the driving power generation unit DPGB. Is supplied to all light emitting diode packages (DP). Accordingly, as shown in FIG. 6A, only white light emitted by the light emitting diode packages DP is emitted from the lighting unit ILN. Accordingly, as shown in FIG. 6A, only white light emitted by the light emitting diode packages DP is emitted from the lighting unit ILN.

FIG. 6B is a view illustrating a state in which only the red light emitting diode chips RD in each light emitting diode package DP included in the lighting unit ILN of FIG. 5 are selectively lit.

That is, when the cutoff signal BS of the power cut-off monitoring unit PCMB is input to the light source driving unit LSDB, the light source driving unit LSDB emits red light of the auxiliary driving power ADPS from the auxiliary power generation / accumulating unit APGB. Supply to diode chips (RD). Accordingly, as shown in FIG. 6B, only the red light emitted by the red light emitting diode chips RD is emitted from the lighting unit ILN. At this time, the red light emitting diode chips RD may blink while being turned on and off at a specific period under the control of the light source driver LSDB.

In addition, even when the forced emergency signal FES is input to the light source driver LSDB from the outside, as shown in FIG. 6B, only the red light emitted by the red light emitting diode chips RD is emitted from the illumination unit ILN. . At this time, the red light emitting diode chips RD may blink while being turned on and off at a specific period under the control of the light source driver LSDB.

FIG. 6C is a view illustrating a state in which only some of the red light emitting diode chips RD in each light emitting diode package DP included in the lighting unit ILN of FIG. 5 are selectively lit.

That is, when the cutoff signal BS or the forced emergency signal FES is input to the light source driver LSDB, as shown in FIG. 6C, the light source driver LSDB selectively selects some of the red light emitting diode chips RD. Can be lit. That is, as shown in FIG. 6C, the light source driver LSDB may selectively light only the red light emitting diode chips RD included in the light emitting diode packages DP positioned in even-numbered rows. At this time, the red light emitting diode chips RD may blink while being turned on and off at a specific period under the control of the light source driver LSDB.

In another embodiment, the light source driver LSDB may selectively light only the red light emitting diode chips RD included in the light emitting diode packages DP positioned in odd-numbered rows.

FIG. 6D is another view illustrating a state in which only some of the red light emitting diode chips RD in each light emitting diode package DP included in the lighting unit ILN of FIG. 5 are selectively lit.

That is, when the cutoff signal BS or the forced emergency signal FES is input to the light source driver LSDB, as shown in FIG. 6C, the light source driver LSDB selectively selects some of the red light emitting diode chips RD. By turning on, the illuminated red light emitting diode chips RD may be controlled to display specific characters or symbols. That is, the light source driver LSDB may further include a memory, in which the dot / off information on which of the red light emitting diode chips RD is turned on and which is turned off is stored in advance. Therefore, the light source driver LSDB selectively lights some of the red light emitting diode chips RD based on the information stored in the memory, thereby turning on the red light emitting diode chips RD as shown in FIG. 6C. It can be used to display symbols such as arrows. At this time, according to the control of the light source driver LSDB, some of the red light emitting diode chips RD may blink while being turned on and off at a specific cycle.

On the other hand, the emergency lighting device according to the invention can be used in conjunction with the emergency bell. That is, when an emergency bell rings in the building, the light source controller detects this and automatically controls the lighting unit ILN to emit red light. At this time, the light source control unit may be further attached to the sound sensor that can selectively detect the sound of the emergency bell.

FIG. 7 is a view illustrating a shape of a printed circuit board (PCB) according to an embodiment of the present invention. As shown in FIG. 7A, the printed circuit board (PCB) may have a square shape. At this time, the square printed circuit board (PCB) may be formed with 600 * 600 light emitting diode packages (DP) and emergency red light emitting diode chips (ERDs) (light emitting diode packages (DP) and emergency red light emitting diode chips). (ERD), including 600 * 600). In addition, 600 * 600 light emitting diode packages DP may be formed on the square printed circuit board PCB.

On the other hand, as shown in Figure 7 (b), the printed circuit board (PCB) may have a rectangular shape. At this time, the rectangular printed circuit board (PCB) may be formed of 300 * 1200 light emitting diode packages (DP) and emergency red light emitting diode chips (ERD) (light emitting diode packages (DP) and emergency red light emitting diode chips). (ERDs), including 300 * 1200). In addition, 300 * 1200 light emitting diode packages DP may be formed on the square printed circuit board PCB.

The printed circuit board PCB illustrated in FIG. 7A or 7B may be applied to the emergency lighting apparatus of the first and second embodiments described above.

As described above, the emergency lighting device according to the present invention emits white light in normal times, but can quickly notify an emergency situation by emitting red light automatically or manually in an emergency. For example, the emergency lighting device according to the present invention can be used where military conditions, fire departments, theaters, emergency centers, disaster-related public offices, etc. need a quick situation in the event of emergency.

In addition, the emergency lighting device according to the present invention can accurately indicate the location of the shelter or exit by flashing the red light in an emergency or by displaying the red light in the form of a specific letter or symbol (for example, an arrow pointing in a specific direction). .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents. Will be clear to those who have knowledge of.

DPGB: drive power generation unit APGB: auxiliary power generation / accumulation part
PCMB: Power cut monitoring unit LSDB: Light source driver
PW: External Power DPS: Drive Power
ADPS: Auxiliary Drive Power BS: Blocking Signal
DP: light emitting diode package RD: red light emitting diode chip
GD: Green light emitting diode chip BD: Blue light emitting diode chip
ILN: Lighting part ERD: Emergency red light emitting diode chip
AT: wireless antenna FES: forced emergency signal

Claims (14)

A plurality of light emitting diode packages emitting white light;
A plurality of emergency red light emitting diode chips emitting red light;
A driving power generation unit configured to generate driving power by receiving external power;
An auxiliary power generation / accumulator configured to generate and accumulate auxiliary driving power by receiving the external power;
A power cut-off monitoring unit that monitors whether the external power is cut off and outputs a cutoff signal when the power is cut off; And
And a light source driver for supplying auxiliary driving power to at least one red light emitting diode chip from the auxiliary power generation / accumulating unit in response to a cutoff signal from the power interruption monitoring unit. The method of claim 1,
When there is no blocking signal from the power cut-off monitoring unit, the light source driving unit supplies driving power from the driving power generating unit to the plurality of light emitting diode packages; And,
There is no blocking signal from the power cut-off monitoring unit, and when a forced emergency signal is input from the outside, the light source driving unit supplies driving power from the driving power generating unit to the plurality of emergency red LED chips. Emergency lighting equipment. The method of claim 1,
A printed circuit board on which the light emitting diode packages and the emergency red light emitting diode chips are mounted; And
Emergency lighting apparatus further comprises a protective cover surrounding the printed circuit board. The method of claim 3, wherein
And the number of light emitting diode packages is greater than or equal to the number of emergency red light emitting diode chips. The method of claim 3, wherein
The plurality of light emitting diode packages are arranged in a row on the printed circuit board;
A plurality of emergency red light emitting diode chips are arranged in a row on the printed circuit board;
An emergency lighting device, characterized in that the emergency red light emitting diode chips are arranged in a row between the light emitting diode packages arranged in a row along one row and the light emitting diode packages arranged in a row along another row adjacent thereto. The method of claim 3, wherein
And when the auxiliary driving power or the driving power is supplied to the at least one emergency red light emitting diode chip, the light source driver supplies the auxiliary driving power or the driving power to all the emergency red light emitting diode chips. The method of claim 3, wherein
When the auxiliary driving power source or the driving power is supplied to the at least one emergency red light emitting diode chip, the light source driving unit causes the light emitting emergency red light emitting diode chips to display any one of specific letters, numbers, and arrows. Or supplying driving power selectively to specific emergency red light emitting diode chips. The method of claim 1,
Each light emitting diode package includes a red light emitting diode chip, a green light emitting diode chip and a blue light emitting diode chip therein. A plurality of light emitting diode packages including a red light emitting diode chip, a green light emitting diode chip, and a blue light emitting diode chip;
A driving power generation unit configured to generate driving power by receiving external power;
An auxiliary power generation / accumulator configured to generate and accumulate auxiliary driving power by receiving the external power;
A power cut-off monitoring unit that monitors whether the external power is cut off and outputs a cutoff signal when the power is cut off; And
And a light source driver for supplying auxiliary driving power to at least one red light emitting diode chip from the auxiliary power generation / accumulating unit in response to a cutoff signal from the power interruption monitoring unit. The method of claim 9,
When there is no blocking signal from the power cut-off monitoring unit, the light source driving unit supplies driving power from the driving power generating unit to the red light emitting diodes, the green light emitting diodes, and the blue light emitting diodes provided in the plurality of light emitting diode packages. To; And,
There is no blocking signal from the power cut-off monitoring unit, and when a forced emergency signal is input from the outside, the light source driving unit supplies driving power from the driving power generating unit to at least one red light emitting diode chip. Emergency luminaires. 11. The method of claim 10,
A printed circuit board on which the plurality of light emitting diode packages are mounted; And
Emergency lighting apparatus further comprises a protective cover surrounding the printed circuit board. The method of claim 11,
and n light emitting diode packages (n being a natural number greater than 1) arranged on the printed circuit board in an i * j matrix (i * j = n). 13. The method of claim 12,
When supplying the auxiliary driving power or the driving power to the at least one red light emitting diode chip, the light source driver is characterized in that the emergency power supply selectively supplies the auxiliary driving power to the red light emitting diode chip in the light emitting diode package located in the even row Lighting equipment. 13. The method of claim 12,
When the auxiliary driving power or the driving power is supplied to the at least one red light emitting diode chip, the light source driver specifies the auxiliary driving power so that the light emitting red light emitting diode chips display any one of a specific letter, number, and arrow. Emergency lighting equipment, characterized in that the selective supply of red light emitting diode chips.

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