JP5560217B2 - LED lighting control system - Google Patents

Description

  The present invention relates to an LED illumination control system for controlling the illuminance of an LED used by being attached to a building member such as a handrail of a veranda.

  In general, when laundry is dried on the veranda at night, it is known that if the indoor lighting is blocked by a curtain or the like, the veranda becomes dark and the clothes drying operation becomes very difficult. Then, in order to eliminate such a problem, for example, it is possible to perform a clothesline operation using an LED lighting device as described in Patent Document 1.

JP 2010-097663 A

  However, the LED lighting device as described above can only illuminate the surrounding area with a fixed illuminance, and the illuminance of the LED cannot be freely changed. Therefore, even if the illuminance of the LED is low, even if it is a sufficient time zone, the illuminance is fixed, so the surroundings must always be illuminated with the same illuminance, and there is a problem that wasteful power is consumed. .

  In view of the above problems, an object of the present invention is to provide an LED illumination control system that can freely change the illuminance of an LED.

Means for solving the above problems will be described with reference numerals in the embodiments described later. The LED lighting control system according to claim 1 includes a main body case 12 fitted and fixed to a concave groove (illuminating device mounting concave groove 10) provided in a building member of a handrail headboard 2 of a veranda, and the main body case 12. A plurality of LED boards 14 mounted at predetermined intervals in the inner longitudinal direction, each of which is mounted with an LED 6;
Illuminance time setting means (timer switch unit 101, illuminance setting unit 103) capable of setting the illuminance for each predetermined time of the LED 6,
PWM signal generation means (PWM signal generation unit 104) for generating a PWM signal for changing the illuminance of the LED 6;
In the illuminance time setting means (timer switch unit 101, illuminance setting unit 103), a low illuminance is set in a time zone when the passage of the veranda where the LED 6 is used is not dark, and in a time zone when the light is dark High illuminance is set,
The PWM signal generation unit (PWM signal generation unit 104) generates a PWM signal corresponding to the illuminance set by the illuminance time setting unit (timer switch unit 101, illuminance setting unit 103), and the generated PWM The illuminance of the LED 6 is changed by a signal .

On the other hand, the LED illumination control system according to claim 2 is the LED illumination control system according to claim 1 , wherein the LED control unit 100 detects the amount of light around the area where the LED 6 is used. Sensor 107a), light amount determination means (light amount determination unit 107b) for determining whether the light amount detected by the light amount detection means (light sensor 107a) is greater than or less than a predetermined level threshold, and the light amount determination means (light amount determination). is characterized in part 107 b) of the determination result LED driving means (LED driver 102 for controlling oN / oFF of the LED6 depending on) and more to become a.

The LED illumination control system according to claim 3 is the LED illumination control system according to claim 2 , wherein the LED control unit 100 further includes threshold setting means (threshold setting unit) capable of freely setting the threshold. and characterized by comprising further have 107c).

Next, effects of the present invention will be described with reference numerals in the drawings. First, in the LED lighting control system according to the first aspect of the present invention, in the main body case 12 fitted and fixed to the concave groove (the concave groove 10 for attaching the lighting device) provided in the building member of the handrail coping 2 of the veranda. A plurality of LED substrates 14 are attached at predetermined intervals, and LEDs 6 are mounted on the LED substrates 14 respectively. The illuminance time setting means (timer switch unit 101, illuminance setting unit 103) sets the illuminance of the LED 6 low during a time period when the veranda passage is not dark, and sets it high during a dark time period. ing. As a result, the PWM signal generation means (PWM signal generation section 104) generates a PWM signal corresponding to the illuminance set by the illuminance time setting means (timer switch section 101, illuminance setting section 103). The illuminance of the LED 6 is changed by the PWM signal. For this reason, the LED time zone passage veranda is not dark Kuna' it or used, in light of the veranda of the passage with a low illumination intensity, the time zone in which the passage of the veranda darkens the LED is used, The veranda passage where the LEDs are used can be illuminated with higher illumination . Therefore, according to the present invention, it is possible to save electric power as compared with the case where the path of the veranda where the LED is used is always illuminated with the maximum illuminance of the LED 6. Therefore, useless power consumption can be suppressed.

Further, according to the present invention, from the fact that by changing the illuminance of LED6 at P WM signal, the voltage itself does not change, it is possible to suppress the power loss. Furthermore, since the LED 6 is not always lit by changing the illuminance of the LED 6 by the PWM signal, the temperature increase of the LED 6 can be suppressed and the product life of the LED 6 can be kept long.

On the other hand, according to the second aspect of the present invention, the light amount detection means (light sensor 107a) detects the ambient light amount where the LED 6 is used, and determines whether the detected light amount is greater than or less than a predetermined level threshold. The LED driving means (LED driving unit 102) controls lighting / extinguishing of the LED 6 according to the determination result. Therefore, since the lighting / extinguishing of the LED 6 can be controlled according to the surrounding environment where the LED 6 is used, the power consumption can be further reduced.

Further, according to the invention of claim 3 , the threshold setting means (threshold setting unit 107c) can freely set the threshold of the predetermined level, so that it is set according to the surrounding environment where the LED 6 is used. Can do.

(A) is the front view which looked at the handrail of the LED lighting control system which concerns on this invention from the outdoor side, (b) is the AA line expanded sectional view of (a). It is a BB line expanded sectional view of Drawing 1. (A) is an enlarged view of the part shown by the arrow C of FIG. 2, (b) is an enlarged perspective view which shows the state which is going to engage | insert the LED illuminating device shown to (a) in the ditch | groove for lighting device attachment. It is an expansion perspective view which shows LED lighting apparatus. It is a block diagram of a LED control unit. It is a front view of a timer switch part. It is a graph which shows the example of a setting at the time of setting the illumination intensity of LED for every predetermined time. The output width of the PWM signal is shown, (a) is a diagram showing a PWM signal with an output width of 100%, (b) is a diagram showing a PWM signal with an output width of 75%, and (c) is a PWM signal with an output width of 50%. (D) is a figure which shows a PWM signal with an output width of 25%.

  Hereinafter, an embodiment of an LED illumination control system according to the present invention will be specifically described with reference to the drawings. In FIG.1 and FIG.2, what looked at the handrail 40 which comprises a part of LED lighting control system installed in the outdoor side edge part of the veranda from the outdoor side is shown, The columns 1 are erected at regular intervals along the weir wall S provided at the outdoor side end of the veranda passage T, and the handrails 2 are bridged over the upper ends of these columns 1. The lower ends of the columns 1, 1 are connected by a lower frame 3, and a glass plate (panel) 5 is fitted in a section 4 formed by both adjacent columns 1, 1, handrails 2 and the lower frame 3. It is made.

  In more detail, the mounting structure of the glass plate 5 in the section 4 formed by the adjacent support columns 1 and 1, the balustrade headboard 2 and the lower frame 3 will be described. As shown in FIG. 2 and FIG. 2, the columnar column main body 28 and a joint frame 29 projecting from the outdoor side surface of the column main body 28 are formed. The lower frame 3 is interposed between the joint frames 29 and 29 of the supporting columns 1 and 1 facing left and right, and the end of the lower frame 3 is fixed to the supporting column body 28 with screws 30. On the other hand, the upper end portion of the glass plate 5 is fitted into the glass fitting portion 11 of the base frame 8 of the handrail headboard 2 described later, and the left and right end portions are fitted into the glass fitting portion 32 of the joint frame 29. In this state, it is fitted in the compartment 4. Reference numeral 33 denotes a decorative cover, which covers the gap 34 between the opposed end faces of the lower frames 3 and 3 of both sections 4 and 4 facing each other across the joint frame 29 of the support column 1, and both are covered by screws 35. It is fixed to the bottom frame.

  Incidentally, as shown in FIG. 2, the handrail headboard 2 is streamlined so as to cover the base frame 8 made of an aluminum extruded shape and mounted on the upper end surface of the support column 1 and the upper surface side of the base frame 8. The head body 9 is made of an aluminum extruded section that is formed in a shape and is removably engaged and fixed to the base frame 8. And in the cross-sectional shape of the handrail head board 2 whole, the channel | path T side edge part 2a is formed in a comparatively thin streamline type, and the outdoor side edge part 2b of the other side is formed in a comparatively thick streamline type.

  Further, the passage T side end portion 2 a is formed so as to protrude from the passage side surface 1 a of the support column 1 toward the veranda passage T side, and the outdoor side end portion 2 b, which is the end portion on the opposite side of the passage T, is It is formed so as to protrude slightly to the outdoor side from the outer side surface 1b. On the lower surface side of the protruding end portion 2a on the side of the passage T, an LED lighting device 7 in which a large number of LEDs 6 are arranged at regular intervals in the longitudinal direction of the headboard is provided. Can be illuminated. On the other hand, on the lower surface side of the outdoor side end portion 2b, the glass plate 5 is fitted in a section 4 formed by the end portion 2b and the lower columns 3 and the adjacent columns 1 and 1.

  Further, on the lower surface of the base frame 8 forming the handrail headboard 2, as shown in FIG. 2 and FIG. Is recessed along the entire length of the handrail headboard 2. And as shown in FIG. 2, the glass plate fitting part 11 is recessedly provided by the outdoor side edge part 2b of the other side. Further, as shown in FIG. 2 or FIG. 3 (a), engaged portions 8 a and 8 b are formed at both side ends of the base frame 8, and the base frame 8 is engaged at both side ends of the head body 9. Engagement portions 9a and 9b that can be engaged with the engagement portions 8a and 8b are formed. Thereby, the cap body 9 is engaged with and fixed to the base frame 8 so that the engaging portions 9 a and 9 b are engaged with the engaged portions 8 a and 8 b of the base frame 8.

  On the other hand, as shown in FIGS. 3A and 3B, the LED lighting device 7 is recessed along the longitudinal direction of the handrail headboard 2 on the lower surface of the end portion 2 a of the handrail headboard 2 on the passage T side. The lighting device mounting concave groove 10 is fitted and fixed. And as shown in FIG. 4, the said LED lighting apparatus 7 is hold | maintained in the main body case 12 which consists of the aluminum extrusion shape material which can be cut | disconnected by predetermined length, and this longitudinal direction in this main body case 12, A plurality of LED boards 14 each having a plurality of LEDs 6 mounted at fixed positions, a connection wiring 15 for electrically connecting the LED boards 14, and joint connectors 26 and 27 provided at both ends of the connection wiring 15 Become.

  The main body case 12 is made of an aluminum extruded shape, and as shown in FIGS. 3A, 3B and 4, both side wall portions 17 and 18 and lower end side sides of both side wall portions 17 and 18 are provided. A connecting wall 19 that connects the two, a pair of fitting recesses 20 and 21 that are formed opposite to each other so that both side ends of the LED board 14 are fitted to both side ends on the lower surface side of the connecting wall 19, Respectively projecting outwardly at the upper end portions of the side wall portions 17 and 18, respectively, engaging engagement recesses 22 and 23 provided at the back portions of the opposing wall surfaces 10a and 10b of the illumination device mounting recess groove 10, respectively. A pair of engaging projections 24 and 25 on both sides are engaged. And as shown in FIG.3 (b), this main body case 12 carries out fitting holding of the LED board 14 between the lower surface of the connection wall part 19, and a pair of fitting recessed parts 20 and 21 of both sides, and this LED The LED 6 (see FIG. 3A) attached to the lower surface side of the substrate 14 can emit light downward from between the pair of fitting recesses 20 and 21 on both sides. In addition, as shown in FIG. 3B, the both side wall portions 17, 18 have an outer width Wa of both engaging projections 24, 25 formed on the upper end portion so as to face the opposite wall surface 10 a of the illumination device mounting groove 10. , 10b is formed to be slightly larger than the inner width Wb.

  Here, the method for assembling the LED lighting device 7 will be described. First, for example, two LEDs 6 (see FIG. 4) and resistors (not shown) are mounted at predetermined positions on the surface side of each LED board 14, and this The wiring is printed on the back side of the substrate 14 (not shown). Then, in a state where the main body case 12 is repeatedly reversed as shown in FIG. 4, a required number of LED boards 14... The connection wiring 15 is inserted and fitted between the fitting recesses 20 and 21, and these LED substrates 14 are positioned at predetermined intervals as shown in FIG. Electrically connect with. On the other hand, as shown in FIG. 4, the connection wiring 15 has a male terminal 26 and a female terminal 27 of the joint connector attached to both ends, respectively, and, as shown in FIG. A seal member 36 is attached to the lower side of the connecting wall portion 19 of the main body case 12 where the main body case 14 is disposed. The sealing material 36 is formed of a liquid or semi-liquid curable silicon resin or the like, and is filled so that the LED substrate 14 is completely filled and only the surface of the LED 6 is exposed downward. Thereby, waterproofing processing is performed. When the sealing material 36 is formed of a curable silicon resin, the sealing material 36 can be used as a holding member for fixing the LED substrate 14 to the lower side of the connecting wall portion 19.

  The LED lighting device 7 assembled in this way is formed to a length corresponding to the pitch between adjacent columns 1 and 1 of the handrail shown in FIG. The LED lighting device 7 is fitted into the lighting device mounting groove 10 at the passage T side end portion 2a of the handrail headboard 2 sequentially from one end side in the state shown in FIG. It is attached so that the end faces of the main body case 12 are in contact with each other in the illuminating device attaching concave groove 10 over the entire length of the sliding headboard 2. At the time of this attachment, each LED lighting device 7 has a male terminal 26 and a female terminal 27 of a joint connector as shown in FIG. 4 and a male terminal of a joint connector of another LED lighting device 7 in the main body case 12. 26 and the female terminal 27 are electrically connected to each other by engaging the concave and convex portions, and a series of LED illuminating devices 7 are formed over the entire length of the illuminating device mounting groove 10 formed on the entire length of the handrail headboard 2. ... are continuously attached without interruption. Further, the joint connectors 26 and 27 on one end side of the series of LED lighting devices 7... Are electrically connected to the LED control unit 100 shown in FIG. Note that the male terminal 26 and the female terminal 27 of the joint connector may be engaged with each other on the other end side of the series of LED lighting devices 7.

  On the other hand, when the main body case 12 of the LED lighting device 7 is fitted into the groove 10 for mounting the lighting device of the handrail headboard 2, the engaging projections 24 and 25 at the upper ends of the side wall portions 17 and 18 are shown in FIG. ), The outer width Wa is slightly larger than the inner width Wb of the opposing wall surfaces 10a, 10b of the illuminating device mounting groove 10, so that the upper end sides of both side walls 17, 18 are formed into the grooves 10. The engaging protrusions 24 and 25 are pushed in along the wall surfaces 10a and 10b of the concave groove 10 by being pushed in, so that the engaging protrusions 24 and 25 are provided in the deep portions of the wall surfaces 10a and 10b. 23 is engaged. Thereby, the main body case 12 is fixed to the concave groove 10 so as not to be pulled out.

  As shown in FIG. 3, the connecting wall portion 19 of the main body case 12 is formed so as to be inclined at a predetermined angle with respect to the side wall portions 17 and 18. Therefore, the LED board 14 attached along the lower surface of the connecting wall portion 19 is inclined at a predetermined angle with respect to the horizontal plane. Here, for example, if the inclination of the LED board 14 at a predetermined angle is 30 ° ascending indoors with respect to the horizontal plane, the LEDs 6 disposed on the lower surface of the LED board 14 will also be inclined 30 ° with respect to the horizontal plane. The light emitted from the LED 6 of the LED board 14 of the LED lighting device 7 in the use of the handrail is inclined at 30 ° from the passage T-side end 2a of the handrail headboard 2 to the room interior as shown in FIG. It will illuminate the veranda passage. Accordingly, when the laundry is to be dried on the veranda at night, if the LED 6 is caused to emit light as described above, the veranda becomes bright even when indoor lighting is blocked by a curtain or the like, and it becomes very easy to dry clothes. . Further, by using the LED lighting device 7 provided on the lower surface side of the passage T side end portion 2a of the handrail headboard 2, the LED 6 can accurately illuminate a pedestrian's feet in a step or step with a step other than the veranda. Therefore, the safety of pedestrians can be secured sufficiently. In the present embodiment, the LED substrate 14 attached along the lower surface of the connecting wall portion 19 is inclined at a predetermined angle with respect to the horizontal plane.

  On the other hand, the LED control unit 100 controls the illuminance of the LED 6 to change every predetermined time, and is configured as shown in FIG. That is, the LED control unit 100 includes a timer switch unit 101 as shown in FIG. 5, and the timer switch unit 101 can set the predetermined time.

  More specifically, the timer switch unit 101 includes five systems of output circuits CH1 to CH5 as shown in FIG. 6, and the output circuits CH1 to CH5 are switches 101a1 to 101a1 corresponding to the output circuits CH1 to CH5, respectively. In 101a5, “ON” / “OFF” can be set. Further, the timer switch unit 101 has an LCD display unit 101b, and can confirm the current time or the set time of each output circuit CH1 to CH5. The timer switch unit 101 has a mode changeover switch 101c. By switching the mode changeover switch 101c, the setting mode or the operation mode of each of the output circuits CH1 to CH5 can be changed.

  That is, when the mode changeover switch 101c is switched to the setting mode, it is displayed on the LCD display unit 101b by, for example, long pressing the time setting key 101d provided in the timer switch unit 101. The numbers corresponding to the time and the output circuits CH1 to CH5 blink, and the time can be set. Thus, the user sets the operation start time and operation end time of each output circuit CH1 to CH5 to a predetermined time using the time setting keys 101e and 101f, and sets the set time using the set key 101g. be able to. When the mode changeover switch 101c is switched to the operation mode after the set time has been set, each output circuit CH1 to CH5 has a valid signal ("Hi" pulse or "Low") at the set operation start time. Pulse) is output to the LED drive unit 102 (see FIG. 5), and an invalid signal (a pulse opposite to the pulse output at the operation start time) is output to the LED drive unit 102 when the operation end time is reached. A normal invalid signal is output from each of the output circuits CH1 to CH5.

  Further, as shown in FIG. 5, the LED control unit 100 has an illuminance setting unit 103, and sets the illuminance of the LED 6 for each predetermined time set by the timer switch 101 configured as described above. be able to. That is, the illuminance setting unit 103 is provided with five systems of output circuits like the timer switch unit 101, and the illuminance of the LED 6 can be set for each of the five systems of output circuits, and the set illuminance setting value is a PWM signal. It is output to the generation unit 104.

  Specifically, as shown in FIG. 7, in the timer switch unit 101, the operation start time of the output circuit CH1 is set to 18:00, the operation end time is set to 20:00, and the operation start time of the output circuit CH2 is set to 20:00. The time is set to 22:00, the operation start time of the output circuit CH3 is set to 22:00, the operation end time is set to 0:00, the operation start time of the output circuit CH4 is set to 0:00, and the operation end time is set to 2:00, and the operation of the output circuit CH5 is set. When the start time is 2 o'clock and the operation end time is 6 o'clock, the illuminance setting unit 103 sets the illuminance of the LED 6 for each set time. That is, when it is desired to set the illuminance of the LED 6 to 30 lux during the operation of the output circuit CH1, if the maximum illuminance of the LED 6 is set to 60 lux, the illuminance is reduced to half, so “50” is set. Then, when the illuminance of the LED 6 is desired to be 60 lux during the operation of the output circuit CH2, the illuminance is as it is, so “100” or “00” is set. Further, when it is desired to set the illuminance of the LED 6 to 45 lux during the operation of the output circuit CH3, if the maximum illuminance of the LED 6 is set to 60 lux, the illuminance becomes 3/4, so “75” is set. When the output circuit CH4 is in operation and the illuminance of the LED 6 is to be set to 30 lux, the maximum illuminance of the LED 6 is set to 60 lux. If the illuminance of the LED 6 is to be set to 15 lux during the operation of the output circuit CH4, the maximum illuminance of the LED 6 is set to 60 lux. The set values set in this way are output to the PWM signal generation unit 104, respectively. In addition, although the illumination intensity setting part 103 demonstrated in this embodiment showed the example which sets the percentage with respect to the maximum illumination intensity of LED6, you may make it a structure which sets an illumination intensity directly.

  On the other hand, the PWM signal generation unit 104 generates a PWM signal corresponding to the set value set in the illuminance setting unit 103 and outputs the PWM signal to the LED drive unit 102. That is, when the setting value set by the illuminance setting unit 103 is “100” or “00”, the PWM signal generation unit 104 generates the PWM signal shown in FIG. When the setting value set in 103 is “75”, the PWM signal shown in FIG. 8B is generated. When the setting value set in the illuminance setting unit 103 is “50”, When the PWM signal shown in FIG. 8C is generated and the set value set by the illuminance setting unit 103 is “25”, the PWM signal shown in FIG. This is output to the LED drive unit 102.

  On the other hand, the LED drive unit 102 outputs the signal generated by the PWM signal generation unit 104 to the D / A conversion unit 105 based on the output signals of the output circuits CH1 to CH5 output from the timer switch unit 101. is there. Specifically, as shown in FIG. 7, in the timer switch unit 101, when the operation start time of the output circuit CH1 is set to 18:00 and the operation end time is set to 20:00, the output circuit CH1 is more effective during that time. Since the signal is output, the LED drive unit 102 selects the PWM signal (see FIG. 8C) corresponding to the value “50” initially set by the illuminance setting unit 103 based on the valid signal. And output to the D / A converter 105. In the timer switch unit 101, if the operation start time of the output circuit CH2 is set to 20:00 and the operation end time is set to 22:00, an effective signal is output from the output circuit CH2 during that time, and therefore LED driving is performed. The unit 102 selects a PWM signal (see FIG. 8A) corresponding to the value “100” or “00” set second by the illuminance setting unit 103 based on the valid signal, and performs D / A The data is output to the conversion unit 105. In the timer switch unit 101, if the operation start time of the output circuit CH3 is set to 22:00 and the operation end time is set to 0:00, the valid signal is output from the output circuit CH3 during that time, so that the LED drive The unit 102 selects a PWM signal (see FIG. 8B) corresponding to the value “75” set third by the illuminance setting unit 103 based on the valid signal, and sends it to the D / A conversion unit 105. Output. Further, when the operation start time of the output circuit CH4 is set to 0 o'clock and the operation end time is set to 2 o'clock in the timer switch unit 101, the valid signal is output from the output circuit CH4 within that time, so that the LED drive The unit 102 selects a PWM signal (see FIG. 8C) corresponding to the value “50” set fourth by the illuminance setting unit 103 based on the valid signal, and sends it to the D / A conversion unit 105. Output. In the timer switch unit 101, if the operation start time of the output circuit CH5 is set to 2 o'clock and the operation end time is set to 6 o'clock, the valid signal is output from the output circuit CH5 within that time, so that the LED drive Based on the valid signal, unit 102 selects a PWM signal (see FIG. 8D) corresponding to the value “25” last set by illuminance setting unit 103, and outputs the PWM signal to D / A conversion unit 105. It is to do. The D / A conversion unit 105 converts the digital signal output from the LED driving unit 102 into an analog signal and outputs the analog signal to the LED 6.

  Thus, since the illuminance of the LED 6 is changed by the PWM signal as described above, the voltage itself does not change, so that the power loss can be kept low. Furthermore, since the LED 6 is not always lit by changing the illuminance of the LED 6 by the PWM signal, the temperature increase of the LED 6 can be suppressed and the product life of the LED 6 can be kept long. Further, the timer switch unit 101 and the illuminance setting unit 103 can set the illuminance of the LED 6 every predetermined time, so that the user can respond to the environment around the passage T (see FIG. 2) using the LED 6. The illuminance of the LED 6 can be set freely.

  By the way, as shown in FIG. 5, a human sensor 106 and an optical sensor unit 107 are further electrically connected to the LED driving unit 102. The human sensor 106 detects whether or not a person exists within a predetermined range from the human sensor 106, and the detected content is output to the LED driving unit 102. The LED driving unit 102 outputs a PWM signal set every predetermined time described above when detecting a person based on the signal received from the human sensor 106, and when not detecting a person, the PWM driving unit 102 outputs the PWM signal. Stop signal output. Thereby, since LED6 is not lighted unnecessarily, power consumption can be restrained low.

  On the other hand, as shown in FIG. 5, the optical sensor unit 107 includes an optical sensor 107a, a light quantity determination unit 107b, a threshold setting unit 107c, and an optical sensor switch unit 107d. The optical sensor 107a is composed of a photoelectric conversion element such as a photodiode, detects the amount of light around the passage T (see FIG. 2), and outputs the detected amount of light to the light amount determination unit 107b. The light amount determination unit 107b determines whether the detected light amount is greater than or equal to a predetermined level threshold value. If the detected light amount is equal to or less than the predetermined level threshold value, a command signal for turning on the LED 6 is provided. If the detected light amount is equal to or less than a predetermined level threshold, a command signal for turning off the LED 6 is output to the LED drive unit 102. The threshold setting unit 107c can freely set the threshold of the predetermined level, and the set value is output to the light quantity determination unit 107b. Thereby, the setting according to the surrounding environment of the channel | path T (refer FIG. 2) which uses LED6 can be performed. Furthermore, the optical sensor switch unit 107d can turn on / off the operation of the optical sensor 107a, and outputs the set ON / OFF signal to the light amount determination unit 107b. The light quantity determination unit 107b outputs a signal that the operation of the optical sensor 107a is stopped to the LED driving unit 102 when the OFF signal is output from the optical sensor switch unit 107d. That is, in this case, the state is the same as when the optical sensor unit 107 is not electrically connected to the LED driving unit 102.

  On the other hand, the LED drive unit 102 outputs or stops the output of the PWM signal set every predetermined time based on the LED 6 turn-on / off command signal and the human sensor 106 signal. That is, when the signal determined by the light amount determination unit 107b is a command signal for turning on the LED 6, and the human sensor 106 detects a person, the LED driving unit 102 sets the PWM set at the predetermined time described above. Output a signal. When the signal determined by the light amount determination unit 107b is a command signal for turning on the LED 6 and the human sensor 106 does not detect a person, the LED driving unit 102 is set every predetermined time described above. Stop the PWM signal. Further, when the signal determined by the light amount determination unit 107b is a command signal for turning off the LED 6, the LED driving unit 102 is set at the predetermined time described above regardless of whether or not the human sensor 106 detects a person. Stop the PWM signal. Thereby, since LED6 is not lighted unnecessarily, power consumption can be restrained low. In addition to the predetermined time set by the timer switch unit 101, if the signal determined by the light amount determination unit 107b is a command signal for turning on the LED 6 and the human sensor 106 detects a person, Any one of the PWM signals shown in FIGS. 8A to 8D may be output from the drive unit 102.

  Thus, according to the embodiment described in detail above, the plurality of LED boards 14 are provided in the main body case 12 fitted and fixed to the lighting device mounting concave groove 10 provided in the building member such as the handrail headboard 2. The LEDs 6 are mounted at predetermined intervals, and the LEDs 6 are mounted on the respective LED boards 14. The illuminance of these LEDs 6 can be changed by the LED control unit 100 every predetermined time. Therefore, for example, as shown in FIG. 7, it is possible to illuminate the surroundings with a low illuminance during a time period when the surroundings are not so dark, and illuminate the surroundings with a higher illuminance during a time period when the surroundings are dark. Therefore, according to the present embodiment, compared with the case where the surroundings are illuminated with the maximum illuminance of the LED 6, the power in the shaded portion shown in FIG. 7 can be saved, so that useless power consumption can be suppressed.

  Although not shown in the present embodiment, the power source of the LED control unit 100 may be an external power source or a built-in battery.

  Further, in the present embodiment, an example in which two human sensors 106 and optical sensor units 107 are provided has been described, but it goes without saying that only human sensors or only optical sensor units may be provided.

  Furthermore, according to the present embodiment, the example in which the setting of the illuminance for each predetermined time of the LED 6 is set using the timer switch unit 101 and the illuminance setting unit 103 has been shown. The setting unit 103 may be integrated (for example, the illuminance can be set by the apparatus shown in FIG. 6). In the present embodiment, the timer switch unit 101 and the illuminance setting unit 103 are provided with five output circuits. However, the number is not limited to five, and any number of systems may be used.

2 Handrail Kasagi 6 LED
10 Groove for mounting lighting device (concave groove)
12 body case 14 LED board 100 LED control unit 101 timer switch part (illuminance time setting means)
102 LED drive unit (LED drive means)
103 Illuminance setting unit (illuminance time setting means)
104 PWM signal generator (PWM signal generator)
107 optical sensor 107a optical sensor (light quantity detection means)
107b Light quantity determination unit (light quantity determination means)
107c Threshold setting unit (threshold setting means)

Claims (3)

A body case to be fitted and fixed in the concave groove provided in the building elements of the handrail Rikasa wood veranda
A plurality of LED boards each mounted with a LED mounted at predetermined intervals in the longitudinal direction in the main body case;
Illuminance time setting means capable of setting the illuminance every predetermined time of the LED;
PWM signal generating means for generating a PWM signal for changing the illuminance of the LED,
In the illuminance time setting means, a low illuminance is set in a time zone when the veranda passage where the LED is used is not dark, and a high illuminance is set in a dark time zone,
The PWM signal generation means generates a PWM signal corresponding to the illuminance set by the illuminance time setting means, and changes the illuminance of the LED by the generated PWM signal . A light intensity detection means for detecting the amount of ambient light that before Symbol LED is used, the amount of light detected by said light amount detecting means and the quantity determining means for determining whether or not more than the predetermined level threshold, the light amount determining means The LED illumination control system according to claim 1 , further comprising: an LED driving unit that controls lighting / extinction of the LED according to a determination result. LED lighting control system of claim 2, the pre-Symbol threshold formed by a freely settable threshold value setting means further.

Images