KR101317462B1 - Tunnel light system - Google Patents

Abstract

PURPOSE: A tunnel lamp system is provided to reduce power consumption by constantly maintaining the luminous output of a tunnel lamp regardless of a temporary illumination change outside a tunnel. CONSTITUTION: A plurality of tunnel lamps (10) are commonly connected to an AC power source line. The tunnel lamps are regularly arranged in a tunnel. An illumination sensor senses illumination outside the tunnel. A time setting unit (23) sets effective illumination recognition time. A control unit (25) controls the irradiance of the tunnel lamp. [Reference numerals] (11) LED module; (13) Constant current conversion unit; (15) Dimming unit; (21) A-D conversion unit; (23) Time setting unit; (25) Control unit

Description

Tunnel light system

The present invention relates to a system such as a tunnel to adjust the illuminance inside the tunnel in accordance with the illuminance of the outside.

Unlike general roads, tunnels are narrow spaces, and during the daytime, the intensity difference between the inside and outside of the tunnel is changed rapidly. As such, the amount of light emitted from the tunnel and the like installed inside the tunnel must be adjusted according to the illuminance outside the tunnel to correspond to the eye compliance.

As an example of a technique for adjusting the light emission amount of the tunnel light, a tunnel light control device is disclosed in Korean Patent No. 10-1182728. The tunnel light control device detects illuminance outside the tunnel using an illuminance sensor and adjusts the amount of light emitted from the tunnel according to the detected external illuminance.

The illuminance outside the tunnel in which the illuminance sensor is installed may be temporarily changed due to the environmental characteristics of the tunnel. As such, the amount of light emitted from the tunnel or the like can also be unnecessarily increased or decreased. As a result, illuminance inside the tunnel may be temporarily unstable, and of course, unnecessary power consumption may be caused.

Korea Patent Registration No. 10-1182728 (September 07, 2012)

Embodiments of the present invention relate to a tunnel light system for solving the above problems.

The embodiments provide a system such as a tunnel suitable for stably maintaining the illuminance inside the tunnel even when the illuminance changes temporarily outside the tunnel.

In addition, the present embodiments provide a tunnel light system suitable for preventing unnecessary power consumption.

Tunnel lamp system according to an embodiment of the present invention includes: a plurality of tunnel lamps connected in common to the AC power line and disposed at regular intervals in the tunnel; An illuminance sensor detecting an illuminance outside the tunnel; A time setting unit for setting an effective illuminance recognition time; And checking whether the current sensed illuminance sensed by the illuminance sensor has a difference that is at least as much as a preset minimum illuminance control width than the effective sense illuminance, and wherein the current detection has a difference that is greater than the minimum illuminance control range compared to the effective sense illuminance. Check whether illumination is maintained for at least the effective illuminance recognition time set by the time setting unit, and wherein the current sensed illuminance having a difference in the at least minimum illuminance control range compared to the effective sense illuminance is at least the effective sense illuminance recognition time And a control unit for allowing the effective sensing illuminance to be updated to have a value of the current sensing illuminance only when it is maintained for a while, and adjusting the irradiance of the plurality of tunnels and the like based on the updated effective sensing illuminance.

As described above, the tunnel lamp system according to the embodiment of the present invention allows the amount of light emitted from the tunnel lamp to be kept constant regardless of the temporary illuminance change outside the tunnel. As such, the illuminance inside the tunnel is not unnecessarily adjusted. Therefore, the tunnel lamp system according to an embodiment of the present invention can be stably maintained irrespective of a temporary change in illuminance outside the tunnel, and can also prevent unnecessary power consumption.

1 is a block diagram showing the configuration of a tunnel light system according to an embodiment of the present invention.
FIG. 2 is a detailed circuit diagram showing the configuration of the dimming unit disclosed in FIG. 1 in detail.
3 is a block diagram showing the configuration of a tunnel light system according to another embodiment of the present invention.
Figure 4 is a block diagram showing the configuration of a tunnel light system according to another embodiment of the present invention.
5 is a detailed circuit diagram showing in detail the configuration of the constant current conversion module and the LED module disclosed in FIG.
6 is a flowchart illustrating a tunnel light control method according to an embodiment of the present invention.

Hereinafter, a tunnel light system according to preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings such that those skilled in the art can easily implement the present invention. In the detailed description of the embodiments of the present disclosure, when it is determined that detailed descriptions of related well-known configurations or functions may obscure the gist of the present disclosure, the detailed description may be omitted.

In the present invention, the "current sensing illuminance" is the illuminance that the illuminance sensor is currently detected, and the data generated by the "current sensing illuminance" is the current illuminance detection data Lp.

In addition, in the present invention, the "effective sensing illuminance" is a sensing illuminance immediately before the "current sensing illuminance" is input, and has a difference of at least the minimum illuminance control width Ls as compared to the immediately preceding sensing illuminance. The generated data is “effective illuminance detection data (Le)”.

In addition, in the present invention, the "reference illuminance" data is the illuminance standard in the tunnel, which is a value that can be changed depending on the installation place or the place where the illuminance is to be maintained. It can be detected by the illumination sensor for detecting the value stored in the memory controlled by the controller.

In addition, in the present invention, the "minimum illuminance control width Ls" is a value which is set in advance by the manufacturer of the present invention and stored in a memory, etc., and the difference between the illuminance deviation (ΔLd) reference illuminance and the effective sensing illuminance. Value.

In addition, in the present invention, even if the illuminance outside the tunnel changes by a certain amount or more, a signal generated when the change in the illuminance is recognized as valid only at least when the effective illuminance recognition time continues is a “effective illuminance detection signal”.

1 is a block diagram illustrating a tunnel lamp system according to an exemplary embodiment of the present invention. FIG. 2 is a detailed circuit diagram showing the configuration of the dimming unit disclosed in FIG. 1.

Referring to FIG. 1, a tunnel lamp system according to an embodiment of the present invention controls a plurality of tunnel lamps 10 that commonly input AC power (for example, 220V), and the tunnel lamps 10. And a control unit 20. The AC power may be supplied to the plurality of tunnel lamps 10 through single phase AC power lines P and N. P-phase power lines are commonly referred to as hot lines, and N-phase power lines are referred to as neutral lines or ground lines.

The plurality of tunnel lights 10 may be arranged at regular intervals inside the tunnel. In addition, each of the plurality of tunnel lamps 10 may include a light emitting diode (hereinafter, referred to as LED) module 11, a constant current converter 13, and a network 15.

The LED module 11 may include a plurality of LED arrays not shown. The plurality of LED arrays may be connected in parallel with each other. Each of the LED arrays includes a plurality of LEDs connected in series. The LED module 11 may emit a light amount according to the magnitude of the driving voltage from the constant current converter 13.

The constant current converter 13 converts the dimmed AC voltage from the dimming unit 15 into a constant current-DC voltage. While the DC voltage converted by the constant current converter 13 maintains a constant current, it has a voltage level that varies with the dimming amount of the dimming unit 15. In addition, the converted DC voltage is used as a driving voltage of the LED module 11. To this end, the converted DC voltage is supplied from the constant current converter 13 to the LED module 11.

The dimming unit 15 dims the AC power supplied from the AC power lines P and N to the constant current converter 13 so that the driving voltage supplied to the LED module 11 is adjusted. The dimming amount of the AC power by the dimming unit 15 may be adjusted according to the logic value of the dimming control signal DCS supplied from the control unit 20. For example, the dimming unit 15 may increase or decrease the phase width of the AC power supplied to the constant current converter 13 according to a logic value of the dimming control signal DCS from the control unit 20. It is not limited to this. In this case, the dimming unit 15 may be configured as shown in FIG. 2.

Referring to FIG. 2, the dimming unit 15 includes one triac, one diac, one capacitor C1, second to seventh resistors R2 to R7, and a first capacitor. To fifth relays RL1 to RL5. The triac TRIAC may be connected between any one of both AC power lines P and N (for example, P-phase power line P) and an input terminal of one side of the constant current converter 13. The diac (DIAC) may be connected between the control terminal of the triac (TRIAC) and the connection node (CN). The capacitor C1 may be connected between the connection node CN and an input terminal of one side of the electrostatic converter 13. The second to seventh resistors R2 to R7 may be connected in series between the connection node CN and the P-phase AC power line P. The first to fifth relays RL1 to RL5 may be connected in parallel to the corresponding third to seventh resistors R3 to R7. In addition, the first to fifth relays RL1 to RL5 may be turned on / off according to logic values of the corresponding first to fifth dimming control signals DCS1 to DCS5.

As the number of the relays turned on among the first to fifth relays RL1 to RL5 is smaller, the resistance value between the P-phase AC power line P and the connection node CN increases and the connection node CN The time constant in e becomes larger. As such, the period from the zero-crossing point of the AC power source to the time point at which the DIAC is turned on becomes longer. Accordingly, the phase width of the AC power transmitted from the P-phase AC power line P toward the constant current converter 13 is reduced via the TRAC. As a result, the driving voltage supplied from the constant current converter 13 to the LED module 11 is lowered, and the amount of light emitted from the LED module 11 is also reduced.

For example, when all of the first to fifth dimming control signals DCS1 to DCS5 have a low logic state, all of the first to fifth relays RL1 to RL5 are turned off. In addition, the resistance value between the P-phase AC power line P and the connection node CN is not only maximum, but also the time constant at the connection node CN is also maximum. As such, the period from the zero-crossing point of the AC power supply to the point of time when the DIAC is turned on is maximized. Accordingly, the phase width of the AC power transmitted from the P-phase AC power line P toward the constant current converter 13 via the TRAC is minimized. As a result, the driving voltage supplied from the constant current converter 13 to the LED module 11 is also lowered to a minimum, and the amount of light emitted from the LED module 11 is also reduced to a minimum.

On the contrary, when all of the first to fifth dimming control signals DCS1 to DCS5 have a high logic state, all of the first to fifth relays RL1 to RL5 are turned on. In addition, the resistance value between the P-phase AC power line P and the connection node CN is minimized, and the time constant at the connection node CN is also the first. As such, the time period from the zero-crossing point of the AC power supply to the point of time when the DIAC is turned on is minimized. As a result, the phase width of the AC power transmitted from the P-phase AC power line P toward the constant current converter 13 through the TRAC is maximized. As a result, the driving voltage supplied from the constant current converter 13 to the LED module 11 also increases to the maximum, and the amount of light emitted from the LED module 11 also increases to the maximum.

Referring back to FIG. 1, the control unit 20 may generate the dimming control signal DCS whose logic value changes according to the illumination of the outside of the tunnel. The dimming control signal DCS may be supplied from the control unit 20 to the dimming unit 15 in the tunnel lamp 10. The dimming control signal DCS may include the first to fifth dimming control signals DCS1 to DCS5 as illustrated in FIG. 1, but is not limited thereto. In addition, the control unit 20 may recognize that even if the illuminance outside the tunnel changes by more than a certain size, it is valid only when the change in the illuminance lasts at least the effective illuminance recognition time. When the illuminance change outside the tunnel is recognized as valid, the control unit 20 transmits the dimming control signal DCS according to the effective illuminance detection signal to the dimming units 15 of the tunnel lights 10. Can supply For this purpose, the control unit 20 includes an illuminance sensor CDS, a first resistor R1, an analog-digital converter (A-D), a time setter 23, and the like. ) And the controller 25.

The illuminance sensor CDS and the first resistor R1 may be connected in series between a DC supply voltage line VCC and a DC ground line GND. The connection point between the illuminance sensor CDS and the first resistor R1 may be connected to an input terminal of the A-D converter 21. The illuminance sensor CDS has a resistance value that decreases as the external illuminance increases. As such, the voltage dropped by the first resistor R1 is increased according to external illuminance.

The A-D converter 21 converts the current illuminance detection signal Lp from the connection point between the illuminance sensor CDS and the first resistor R1 in the form of a digital signal. The current illuminance detection data Lp generated by the A-D converter 21 may be supplied to the controller 25.

The time setter 23 may set an effective illuminance recognition time Td by an operator or a manufacturer. For this purpose, the time setter 23 may include a plurality of key switches or at least one decimal position rotary digital code switch. The effective illuminance recognition time Td may be set to about several seconds to Several minutes. In addition, the effective illuminance recognition time Td may be supplied from the time setter 23 to the controller 25.

The controller 25 may check whether the current illuminance detection data Lp from the A-D converter 21 is larger or smaller than the effective illuminance detection data Le by at least the minimum illuminance control width Ls. In addition, the controller 25 may be configured such that the current sensed illuminance data Lp, which is larger or smaller than the effective sensed illuminance data Le by at least the minimum illuminance control width Ls, is set by the time setter 23. It can be checked whether or not the effective illuminance recognition time Td is maintained. When the current illuminance detection data Lp having a difference between the effective illuminance detection data Le and at least the minimum illuminance control width Ls is maintained for the effective illuminance recognition time Td, the controller 25 is configured to perform the control. The effective illuminance detection data Le may be updated to have a value of the current illuminance detection data Lp, and the logic value of the dimming control signal DCS may be adjusted based on the updated effective illuminance detection data Le. . The dimming control signal DCS adjusted as described above is supplied from the control unit 25 to the dimming unit 15 of the tunnel lamp 10 so that the irradiance of the LED module 11 is adjusted to be high or low. As the controller 25, a microcomputer including a memory may be used. Alternatively, the controller 25 may be implemented in a form including a processor and a memory.

In this way, the radial illuminance of the tunnel lights 10 may be adjusted only when the illuminance outside the tunnel, which is changed by more than the minimum illuminance control width Ls, is maintained by at least the effective illuminance recognition time. As such, irrespective of the temporary illuminance change outside the tunnel, the amount of light emitted from the tunnel can be kept constant, and the illuminance inside the tunnel is not unnecessarily adjusted. Therefore, the tunnel lamp system according to an embodiment of the present invention can be stably maintained irrespective of a temporary change in illuminance outside the tunnel, and can also prevent unnecessary power consumption.

3 is a block diagram illustrating a tunnel lamp system according to another exemplary embodiment of the present invention. Components of FIG. 3 that function and function the same as the components of FIG. 1 may be referred to by the same names and reference numerals. In addition, in order to avoid duplication of description, detailed descriptions of the components of FIG. 3 having the same functions and functions as the components of FIG. 1 may be omitted.

Referring to FIG. 3, a tunnel lamp system according to another embodiment of the present invention controls a plurality of tunnel lamps 30 that commonly input AC power (for example, 220V), and the tunnel lamps 30. And a control unit 22. The AC power may be supplied to the plurality of tunnel lamps 30 through single phase AC power lines P and N.

The plurality of tunnel lamps 30 may be arranged at regular intervals in the tunnel. In addition, each of the tunnel lights 30 may include an LED module 31, a constant voltage converter 33, and a pulse width modulation (PWM) converter 35.

The LED module 31 may include a plurality of LED arrays not shown. The plurality of LED arrays may be connected in parallel with each other. Each of the LED arrays may include a plurality of LEDs connected in series.

The constant voltage converter 33 converts the AC voltage from the AC power lines P and N into a constant voltage. The constant voltage converted by the constant voltage converter 33 may maintain a constant current and voltage level. In addition, the constant voltage may be supplied from the constant voltage converter 33 to the PWM converter 35.

The PWM converter 35 may convert the constant voltage supplied from the constant voltage converter 33 to the LED module 31 in the form of a PWM signal. The pulse width of the PWM voltage supplied from the PWM converter 35 to the LED module 31 may be adjusted according to the voltage level of the width control signal WCS supplied from the control unit 22. For example, as the voltage level of the width control signal WCS increases, the pulse width of the PWM voltage supplied to the LED module 31 may increase. Accordingly, the amount of light emitted from the LED module 31 may increase. In other words, as the voltage level of the width control signal WCS increases, the pulse width of the PWM voltage increases, so that the illumination intensity of the LED module 31 may also increase.

The AC power supplied to the constant current converter 13 is dimmed from the AC power lines P and N to adjust the driving voltage supplied to the LED module 11. The dimming amount of the AC power by the dimming unit 15 may be adjusted according to the logic value of the dimming control signal DCS supplied from the control unit 20. For example, the dimming unit 15 may increase or decrease the phase width of the AC power supplied to the constant current converter 13 according to a logic value of the dimming control signal DCS from the control unit 20. It is not limited to this. In this case, the dimming unit 15 may be configured as shown in FIG. 2.

The control unit 22 may generate the width control signal WCS whose voltage level changes according to the illumination of the outside of the tunnel. The width control signal WCS may be supplied from the control unit 22 to the PWM converter 35 in the tunnel lamp 30. In addition, the control unit 22 may recognize that even if the illuminance outside the tunnel changes by more than a certain size, it is effective only when the change in the illuminance lasts at least the effective illuminance recognition time. When the illuminance change outside the tunnel is recognized as valid, the control unit 22 transmits the width control signal WCS according to the effective illuminance detection signal to the PWM converters 35 of the tunnel lights 30. Can be supplied to To this end, the control unit 22 includes an illuminance sensor CDS, a first resistor R1, an AD converter 21, a time setter 23, a controller 25, and a digital-analog. 'D-A' may comprise a converter (27). The function and operation of the illuminance sensor CDS, the first resistor R1, the A-D converter 21 and the time setter 23 may be easily understood by those skilled in the art through the detailed description of FIG. 1. As such, detailed descriptions of the illuminance sensor CDS, the first resistor R1, the A-D converter 21, and the time setter 23 will be omitted.

The controller 25 may check whether the current illuminance detection data Lp from the A-D converter 21 is larger or smaller than the effective illuminance detection data Le by at least the minimum illuminance control width Ls. In addition, the controller 25 is configured to set the current sensed illuminance data Lp that is larger or smaller than the effective sensed illuminance data Le by at least the minimum illuminance control width Ls by the time setter 23. It can be checked whether the illumination intensity recognition time Td or more is maintained. When the current illuminance detection data Lp having a difference of at least the minimum illuminance control width Ls from the effective illuminance detection data Le is maintained for the effective illuminance recognition time Td, the control unit 25 is configured to perform the control. The effective illuminance detection data Le may be updated to have a value of the current illuminance detection data Lp and the logical value of the width control data may be adjusted based on the updated effective illuminance detection data Le. The adjusted width control data may be supplied from the controller 25 to the D-A converter 27.

The D-A converter 27 converts the width control data from the controller 25 into the width control signal WCS in the form of an analog signal. The width control signal WCS output from the D-A converter 27 may be changed within a voltage range of approximately 0 to 10V. The width control signal WCS may be supplied from the D-A converter 27 to the PWM converters 35 in the tunnel lights 30. Accordingly, the illuminance of the LED module 31 is adjusted to be high or low.

In this way, the radial illuminance of the tunnel lights 30 may be adjusted only when the illuminance outside the tunnel changed by at least the minimum illuminance control width Ls is maintained by at least the effective illuminance recognition time. As such, irrespective of the temporary illuminance change outside the tunnel, the amount of light emitted from the tunnel can be kept constant, and the illuminance inside the tunnel is not unnecessarily adjusted. Therefore, the tunnel lamp system according to an embodiment of the present invention can be stably maintained irrespective of a temporary change in illuminance outside the tunnel, and can also prevent unnecessary power consumption.

Figure 4 is a block diagram showing a tunnel light system according to another embodiment of the present invention. FIG. 5 is a detailed circuit diagram showing the configuration of the constant current conversion module and the LED module disclosed in FIG. 4.

Referring to FIG. 4, a tunnel lamp system according to another embodiment of the present invention includes a plurality of tunnel lamps 40 commonly connected to a modulated AC power line, a single-phase AC power line (P, N), and the modulated AC power. It may include a control unit 24 connected between the power lines. AC power (for example, 220V) may be supplied to the control unit 24 through the single phase AC power lines P and N. The modulated AC power line may be supplied with a modulated AC power on which an operation control signal OCS is modulated. The operation control signal OCS may be included in the modulated AC power in a phase or amplitude modulated form.

The plurality of tunnel lights 40 may be arranged at regular intervals inside the tunnel. In addition, each of the tunnel lights 40 may include an LED module 41, a constant current conversion module 43, a demodulator 45, and a sub controller 47.

The LED module 41 may include a plurality of LED arrays. Each of the plurality of LED arrays may comprise a plurality of LEDs connected in series. For example, the LED module 41 may include first to fifth LED arrays 41A to 41E as shown in FIG. 5. Each of the first to fifth LED arrays 41A to 41E may be driven by a constant current separately supplied from the constant current conversion module 43 to emit a constant amount of light.

The constant current conversion module 43 may supply / block drive current individually to the LED array in the LED module 41. To this end, the constant current conversion module 43 may include a plurality of constant current converters corresponding to the plurality of LED arrays in the LED module 41. For example, the constant current conversion module 43 may include first to fifth electrostatic converters corresponding to the first to fifth LED arrays 41A to 41E in the LED module 41 as illustrated in FIG. 5. 43A-43E). The first to fifth constant current converters 43A to 43E may commonly input the modulated AC power MAC from the modulated AC power line. In addition, each of the first to fifth constant current converters 43A to 43E may convert the modulated alternating current power source MAC into a constant current. The constant current generated in the first to fifth constant current converters 43A to 43E may have a constant current amount and a constant voltage level. In addition, the first to fifth constant current converters 43A to 43E may individually and selectively perform the constant current conversion operation according to a logic state of the corresponding first to fifth operation control signals OCS1 to OCS5. For example, the first constant current converter 43A performs the constant current conversion operation when the first operation selection signal OCS1 has a high logic to correspond to the converted constant current to the first LED array 41A. Can be supplied to The second constant current converter 43B may perform the constant current conversion operation when the second operation selection signal OCS2 has a high logic to supply the converted constant current to the corresponding second LED array 41B. . In this form, the third to fifth constant current converters 43C to 43E also perform the constant current conversion operation when the corresponding third to fifth operation control signals OCS3 to OCS5 have a high logic to perform the conversion. Constant current may be supplied to the corresponding third to fifth LED arrays 41C to 41E.

The demodulator 45 may input the modulated alternating current (MAC) from the modulated alternating current power line. In addition, the demodulator 45 may demodulate the modulated alternating current power source (MAC) to restore the operation control data. To this end, the demodulator 45 may demodulate or phase demodulate the modulation AC power supply (MAC). Such a demodulator 45 may be implemented by a known phase demodulation circuit or a known amplitude demodulation circuit.

The sub controller 47 may generate the operation control signal OCS according to a logic value of the operation control data from the demodulator 45. The operation control signal OCS may include the first to fifth operation control signals OCS1 to OCS5, but is not limited thereto. In addition, the sub controller 47 controls the operation control signal OCS corresponding to the logic value of the previous operation control data until the updated operation control data having the changed logic value is input from the demodulator 45, that is, The logic states of the first to fifth operation control signals OCS1 to OCS5 may be maintained. In addition, the sub controller 47 performs some or all of the first to fifth constant current converters 43A to 43E by using the first to fifth operation control signals OCS1 to OCS5. It can be done. Through this, the sub-controller 47 causes some or all of the first to fifth LED arrays 41A to 41E in the LED module 41 to emit light to adjust the irradiance of the LED module 41. I can regulate it. In other words, the sub-controller 47 may select any one of the first to fifth LED arrays 41A to 41E by adjusting the logic state of the first to fifth operation control signals OCS1 to OCS5. Three, four, or all of them may be driven so that the irradiance of the LED module 41 may be adjusted. Such a sub controller 47 may be implemented by a microprocessor or controllable buffer.

The control unit 24 may generate the operation control data OCS whose logic value changes according to the illuminance outside the tunnel. The operation control data OCS may be supplied from the control unit 24 to the demodulator 45 in the tunnel lamp 40 in a modulated form. In addition, the control unit 24 may recognize that even if the illuminance outside the tunnel changes by more than a certain size, it is effective only when the change in the illuminance lasts at least the effective illuminance recognition time. When the illuminance change outside the tunnel is recognized as valid, the control unit 24 transmits the operation control data OCS to the demodulators 45 of the tunnel lights 40 according to the effective illuminance detection signal. Can supply To this end, the control unit 24 may include an illumination sensor CDS, a first resistor R1, an AD converter 21, a time setter 23, a controller 25, and a modulator 29. . The function and operation of the illuminance sensor CDS, the first resistor R1, the A-D converter 21 and the time setter 23 may be easily understood by those skilled in the art through the detailed description of FIG. 1. As such, detailed descriptions of the illuminance sensor CDS, the first resistor R1, the A-D converter 21, and the time setter 23 will be omitted.

The controller 25 may check whether the current illuminance detection data Lp from the A-D converter 21 is larger or smaller than the effective illuminance detection data Le by at least the minimum illuminance control width Ls. In addition, the controller 25 sets the current illuminance detection data Lp having a difference by at least the minimum illuminance control width Ls from the effective illuminance detection data Le by the time setter 23. It may be checked whether the effective illuminance recognition time Td or more is maintained. When the current illuminance detection data Lp having a difference in the at least minimum illuminance control width Ls compared to the effective illuminance detection data Le is maintained for more than the effective illuminance recognition time Td, the controller 25 ) Updates the effective illuminance detection data Le to have a value of the current illuminance detection data Lp and based on the updated effective illuminance detection data Le, determines a logical value of the operation control data OCS. I can regulate it. The adjusted operation control data OCS may be supplied from the controller 25 to the modulator 29. The logic value of the operation control data OCS may correspond to the number of LED arrays to be radiated out of the LED arrays in the LED module 41.

The modulator 29 performs phase or amplitude modulation on the AC power AC from the single-phase AC power lines P and N according to bit values of the operation control data OCS from the controller 25. The modulated alternating current power source (MAC) may be generated. The modulated alternating current (MAC) may be supplied from the modulator 29 to the demodulators 45 in the tunnel lights 40 and the constant current conversion modules 43 via the modulated alternating current power line. Such a modulator 29 may be implemented by a known phase modulation circuit or a known amplitude modulation circuit.

In this way, the radial illuminance of the tunnel lights 30 may be adjusted only when the illuminance outside the tunnel changed by at least the minimum illuminance control width Ls is maintained by at least the effective illuminance recognition time. As such, irrespective of the temporary illuminance change outside the tunnel, the amount of light emitted from the tunnel can be kept constant, and the illuminance inside the tunnel is not unnecessarily adjusted. Therefore, the tunnel lamp system according to an embodiment of the present invention can be stably maintained irrespective of a temporary change in illuminance outside the tunnel, and can also prevent unnecessary power consumption.

In addition, the tunnel lamp system of FIG. 4 does not require a separate control line (ie, a width control signal line WCS or a dimming control signal line DCS) unlike the tunnel lamp systems of FIGS. 1 and 3. As such, the tunnel light system of FIG. 4 can simplify the wiring structure.

6 is a flowchart illustrating a tunnel light control method according to an embodiment of the present invention. The flowchart of FIG. 6 can be performed by the control units 20, 22, 24 shown in FIGS. 1, 3 and 4. In more detail, the flowchart of FIG. 6 may be performed by the controller 25 which is commonly disclosed in FIGS. 1, 3, and 4. For convenience of description, the tunnel lamp control method of FIG. 6 will be described as commonly applied to all unless any one of FIGS. 1, 3, and 4 is specified.

The controller 25 may input the current illuminance detection data Lp outside the tunnel from the A-D converter 21 at a predetermined period (for example, several tens of microseconds or several msecs) (step S1). In addition, the controller 25 checks whether the current illuminance detection data Lp has a difference as much as the minimum illuminance control width Ls compared to the effective illuminance detection data Le (step S2). .

When the illuminance difference between the current illuminance detection data Lp and the effective illuminance detection data Le is smaller than the minimum illuminance control width Ls in the step S2, the controller 25 may select any one of the registers in the register. The time counter Tc assigned to one may be initialized (reset) to '0' (step S3).

On the contrary, when the illuminance difference between the current illuminance detection data Lp and the effective illuminance detection data Le is equal to or greater than the minimum illuminance control width Ls in the step S2, the controller 25 is configured to perform the operation. The value of the time counter Tc is increased by '1' (step S4). Subsequently, the controller 25 may check whether the value of the time counter Tc has reached the effective illuminance recognition time Td set by the time setting device 23 (step S5). If it is determined in step S5 that the value of the time counter Tc does not reach the effective illuminance recognition time Td, the controller 25 may return to step S1.

When it is determined in step S5 that the value of the time counter Tc reaches the effective illuminance recognition time Td, the controller 25 causes the current illuminance detection data Lp to have the value. The effective illuminance detection data Le may be updated (step S6). In addition, the controller 25 may calculate the illuminance deviation ΔLd of the updated effective illuminance detection data with respect to the reference illuminance data Lr (step S7). Subsequently, the controller 25 may adjust the value of the dimming control signal DCS, the width control signal WCS, or the operation control signal OCS to increase or decrease by the illuminance deviation ΔLd ( Step S8). The dimming control signal DCS, the width control signal WCS, or the operation control signal OCS, which are increased or decreased adjusted by the illuminance deviation ΔLd, are the dimming unit 15 of FIG. 1 and the PWM of FIG. 3. It may be supplied to the transducer 35 or the sub controller 47 of FIG. 4. As such, the illuminance of the LED module 11 of FIG. 1, the LED module 31 of FIG. 3, and the LED module 41 of FIG. 4 may be increased or decreased.

As described above, the tunnel lamp systems according to the embodiments of the present invention allow the illumination intensity of the tunnel lamp to be adjusted only when the illumination change outside the tunnel of the minimum illumination control width Ls is at least effective illumination recognition time. As such, irrespective of the temporary illuminance change outside the tunnel, the amount of light emitted from the tunnel can be kept constant, and the illuminance inside the tunnel is not unnecessarily adjusted. Accordingly, the system such as the tunnel according to the embodiment of the present invention can stably maintain the illuminance inside the tunnel regardless of the temporary illuminance change outside the tunnel, and can also prevent unnecessary power consumption.

What has been described above are only embodiments for implementing a tunnel light system according to the present invention. As such, the present invention is not limited to the above-described embodiments, and any person having ordinary skill in the art to which the present invention pertains may vary without departing from the spirit and technical spirit of the present invention as described in the claims below. It should be protected to cover the extent to which changes can be made.

10, 30, 40; Tunnel light 11, 31, 41: LED lamp module
13: constant current converter 15; Dimming part
20, 22, 24; Control unit 21; AD converter
23; Time setter 25; The control unit
27; DA converter 29; Modulator
33; Constant voltage converters 35; PWM converter
43: constant current conversion module 45; Demodulator
47; Subcontrollers 41A to 41E; First to fifth LED array
43A-43E; 1st to 5th constant current transducer
C1; Capacitor CDS; Light sensor
R1 to R7; Resistors RL1 to RL5; relay
DIAC; Die solution TRIAC; Triac

Claims (6)

A plurality of tunnels commonly connected to the AC power lines and arranged at regular intervals in the tunnel;
An illuminance sensor detecting an illuminance outside the tunnel;
A time setting unit for setting an effective illuminance recognition time; And
The current sensing illuminance sensed by the illuminance sensor is compared with the effective sensing illuminance to determine whether the difference is at least as small as the minimum illuminance adjustment width, and the current having the difference by at least the minimum illuminance control width is compared with the effective sensing illuminance. Checking whether the detected illuminance is maintained for at least the effective illuminance recognition time, and valid only if the current sensed illuminance having a difference in at least the minimum illuminance control range compared to the effective sense illuminance is maintained for at least the effective illuminance recognition time And a control unit for causing the sensing illuminance to be updated to have a value of the current sensing illuminance, and adjusting the irradiance of the plurality of tunnels based on the updated effective sensing illuminance. The method of claim 1,
The controller generates a dimming control signal in which a control value is adjusted by a difference between the updated effective detection illuminance and a reference illuminance,
Each of the plurality of tunnel lights comprises: an LED module including a plurality of LEDs; A dimming unit dimming the AC power from the AC power line corresponding to the control value of the dimming control signal; And a constant current converter converting the AC power dimmed by the dimming unit into a constant current signal and supplying the converted constant current signal to the LED module. The tunnel lamp system of claim 2, wherein the dimming unit modulates the AC power by a phase corresponding to a control value of the dimming control signal. The method of claim 1,
The controller generates a width control signal whose size is adjusted by a difference between the updated effective detection illuminance and the reference illuminance,
Each of the plurality of tunnel lights comprises: an LED module including a plurality of LEDs; A constant voltage converter for converting AC power from the AC power line into a constant voltage; And a PWM modulator for pulse width modulating the constant voltage from the constant voltage converter according to the width control signal and supplying the pulse width modulated voltage to the LED module. The method of claim 1,
The controller generates an operation control signal for adjusting a control value by a difference between the updated effective detection illuminance and the reference illuminance,
Each of the plurality of tunnel lights comprises: at least a plurality of LED arrays in which a plurality of LEDs are connected in series; A plurality of constant current converters for converting AC power from the AC power line into a form of a constant current signal and supplying the converted constant current signal to a corresponding LED array; And a sub controller configured to control the plurality of constant current converters to be selectively driven according to the operation control signal. The method of claim 5, wherein
A modulator for transmitting the operation control signal from the control unit to the AC power supply on the AC power line and transmitting to the sub control unit such as the tunnel; And
And a plurality of demodulators included in each of the tunnel lamps for demodulating the operation control signal loaded on the AC power supply from the AC power line and supplying the demodulated operation control signal to the corresponding sub control unit. The system such as the tunnel.

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