JP2013098293A - Led lighting device checker - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an LED lighting device checker that facilitates its own normal operation confirmation and inspects the LED lighting device with enhanced reliability.SOLUTION: An LED lighting device checker 1 includes: a current source 2 formed so as to output a current from an output port 11; a self-diagnostic power source 3 formed so as to output a DC current; an input port 4 to input an output of an LED lighting device 12; a pseudo load 5; a connection means 6 that connects the pseudo load 5 to the input port 4 during inspection of the LED lighting device 12, and connects the pseudo load 5 to between outputs of the self-diagnostic power source 3; a current detection means 7 to detect a current passing through the pseudo load 5; an evaluation means 8 that performs evaluation by comparing the current detected by the current detection means 7 and a preset reference value; and a display means 9 to display an evaluation result obtained by the evaluation means 8.

Description

  Embodiments described herein relate generally to an LED lighting device checker that inspects an LED lighting device that lights a light emitting diode.

  Lighting devices using light emitting diodes (LEDs) as light sources are used in various fields. As one of the lighting devices, for example, an LED type air traffic sign lamp installed on a runway or taxiway such as an airport or an airport is known. This LED type air traffic sign lamp includes an LED lighting device that turns on the LED, and controls the lighting of the LED according to a dimming signal.

  Aviation sign lights play an important role in supporting the safe operation of aircraft by providing visual information necessary for aircraft to take off and land and run on the ground. For this reason, for example, a periodic inspection is performed once every several months, and the presence or absence of an abnormal state such as a non-lighting state of the LED type air traffic light is checked. This periodic inspection is carried out at the inspection site by taking the LED type air traffic light from the installation site. A rated current is supplied to the LED lighting device from a constant current power source for inspection, and a predetermined inspection is performed in the rated lighting state of the LED (for example, see Patent Document 1).

  The present applicant has applied for an LED lighting unit inspection device capable of inspecting an LED lighting device in the previously filed invention (Japanese Patent Application No. 2010-145690). This inspection device evaluates the LED drive output of the LED lighting device so that the quality can be judged. The inspection work is made efficient and the burden on the inspection is reduced.

  However, if the inspection device itself does not operate normally, the quality of the LED lighting device cannot be determined or the determination result is incorrect. Further, if the normal operation of the inspection apparatus is not confirmed, the reliability of the determination result cannot be assured. Therefore, even in the inspection apparatus, it is necessary to confirm the operation such as checking the output periodically or at the time of the inspection.

JP 2008-210647 A (page 6, FIG. 1)

  However, the operation check of the LED lighting device inspection device itself has the problem that it takes the same time and effort as when checking the quality of the LED lighting device.

  An object of the present embodiment is to provide a checker for an LED lighting device that can easily check the normal operation of the LED lighting device and can reliably test the LED lighting device.

  The LED lighting device checker according to the present embodiment includes a current source, a power supply for self-diagnosis, an input terminal, a pseudo load, connection means, current detection means, evaluation means, and display means.

  The current source has an output end to which the LED lighting device is connected, and is configured to output current from the output end. The power supply for self-diagnosis is formed so that a direct current can be output. The input terminal inputs the output of the LED lighting device.

  The connection means connects the pseudo load to the input terminal when the LED lighting device is inspected, and connects the pseudo load between the outputs of the power supply for self-diagnosis at the time of self-diagnosis. The current detection means detects the current flowing through the pseudo load.

  The evaluation means compares and evaluates the current detected by the current detection means and a preset reference value, and the display means displays the evaluation result of the evaluation means.

  According to the embodiment of the present invention, a pseudo load is connected between the outputs of the self-diagnosis power supply, the current flowing in the pseudo load is compared with a preset reference value, and the evaluation result is displayed. Thus, it can be expected that the LED lighting device checker can operate normally and the LED lighting device can be normally inspected.

It is a block diagram of the checker for LED lighting devices which shows the embodiment of the present invention. Similarly, it is a schematic plan view of the LED lighting device checker. Similarly, it is a schematic side view of the LED lighting device checker. Similarly, it is a circuit diagram of a part of a checker for an LED lighting device. Similarly, it is a circuit diagram of the remaining part of the checker for LED lighting devices.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  The LED lighting device checker 1 of the present embodiment is configured as shown in FIGS. In FIG. 1, an LED lighting device checker 1 includes a variable current source 2 as a current source, a self-diagnosis power source 3, an input terminal 4, a pseudo load 5, a connection means 6, a current detection means 7, an evaluation means 8, and a display means. 9 and control means 10 are formed. The LED lighting device checker 1 inspects an external LED lighting device 12 that lights an LED load. The LED lighting device 12 is housed in, for example, an LED type air traffic sign lamp installed on a runway or taxiway such as an airport or an airport. The variable current source 2 has an output end 11. The output end 11 and the input end 4 are respectively connected to the input side and the output side of the LED lighting device 12 by cables. The input terminal 4 serves as input terminals 4 a and 4 b for inputting the output of the LED lighting device 12.

  The variable current source 2 is a power source for inspecting the LED lighting device 12, and the AC current input from the commercial AC power source Vs is changed (converted) to an AC current corresponding to a plurality of luminous intensity ratios of the LED load and output. It is formed to be able to output from the end 11. In a state where the LED lighting device 12 is connected to the output terminal 11 and the input terminal 4, the pseudo load 5 and the current detection means 7 are connected between the input terminals 4 a and 4 b of the input terminal 4 by the connection means 6. The pseudo load 5 includes a plurality of pseudo loads 5 a to 5 d provided according to the type of the LED lighting device 12. The connection means 6 connects the pseudo loads 5 a to 5 d corresponding to the LED lighting device 12 to the input terminal 4. The pseudo loads 5a to 5d are each composed of a fixed resistor.

  The self-diagnosis power supply 3 is used as a power supply for self-diagnosis of whether the LED lighting device checker 1 can normally inspect the LED lighting device 12, and the input current of the variable current source 2 is converted to DC. It is formed so as to output a direct current after being converted to. During the self-diagnosis, the pseudo load 5 and the current detection means 7 are connected between the outputs of the self-diagnosis power supply 3 by the connection means 6 via the current adjustment resistor 13. Similarly to the pseudo load 5, the current adjustment resistor 13 includes current adjustment resistors 13 a to 13 c provided according to the type of the LED lighting device 12. The connection means 6 connects the current adjusting resistors 13 a to 13 c and the pseudo loads 5 a to 5 d corresponding to the LED lighting device 12. The resistance values of the current adjusting resistors 13a to 13c are set so that the current flowing through the current detecting means 7, that is, the current flowing through the pseudo loads 5a to 5d becomes a substantially constant value.

  As described above, the connection means 6 connects the pseudo load 5 between the outputs of the self-diagnosis power supply 3 or between the input terminals 4a and 4b of the input terminal 4, and the pseudo loads 5a to 5d and the current adjustment. The resistors 13a to 13c are selected and connected.

  The current detection means 7 is formed so as to detect the current flowing through the pseudo loads 5a to 5d.

  The evaluation means 8 is configured to input the current detected by the current detection means 7 and compare and evaluate the detected current and a preset reference value. That is, in the self-diagnosis, when the detected current is within the range of the reference value, the LED lighting device checker 1 determines that the LED lighting device 12 can be normally inspected, and conversely, the detected current is outside the range of the reference value. If there is, the LED lighting device checker 1 is determined to be abnormal. In the inspection of the LED lighting device 12, if the detected current is within the range of the reference value, it is determined that the LED lighting device 12 is normal, and conversely, if the detected current is outside the range of the reference value, the LED It is determined that the lighting device 12 is defective.

  The display means 9 is formed so as to display the evaluation result obtained by the evaluation means 8. The control means 10 is configured to control the connection means 6, the current detection means 7, the evaluation means 8 and the display means 9 so as to operate sequentially. The evaluation unit 8 and the control unit 10 are formed in the microcomputer 14. The comparison and determination processing of the evaluation means 8 is executed by the CPU (central processing unit) of the microcomputer 14. A series of operations of the connecting means 6, the current detecting means 7, the evaluating means 8 and the display means 9 by the control means 10 is executed based on a program stored in a ROM (Read Only Memory) of the microcomputer 14. In the program, a reference value to be compared with the detected current is written.

  As shown in FIG. 3, the LED lighting device checker 1 includes a main body portion 15 formed in a substantially box shape having a flat portion 15 a inclined portion 15 b and a flat portion 15 c on the upper surface side. The main body portion 15 is installed on the floor surface by a plurality of rubber legs 16 provided on a flat bottom surface portion 15d. An output end 11 of the variable current source 2 and an input end 4 for inputting the output of the LED lighting device 12 are juxtaposed on the side surface 15 e of the main body 15.

  The plane part 15a and the inclined part 15b of the main body part 15 are an operation part and a display part. As shown in FIG. 2, the flat portion 15a is provided with an operation knob 17a of a slidac (registered trademark) 17 for adjusting the output current of the variable current source 2, and the inclined portion 15b has a power supply with a display lamp. A switch 18 is provided. In addition, an ammeter 19 for displaying the output current of the variable current source 2 is provided on the inclined portion 15b, and display units 20a to 20c for dimming taps to be selected are provided on the side, and further on the side. Are provided with a display unit 21a for displaying normal (OK) of the LED lighting device 12 and a display unit 21b for displaying failure (NG).

  The dimming tap indicates a plurality of luminous intensity ratios of the LED load. The luminous intensity ratios are 100%, 25%, and 5%. The output currents of the variable current source 2 at this time are 6.6 A (tap 5), 5.2 A (tap 4), and 4.1 A (4.1A, respectively). Tap 3). The output current is varied by the slider 17 and when the output current is reached, the display units 20a to 20c are turned on.

  Display portions 22a and 22b for displaying the inspection results of the LED lighting device checker 1 itself are provided beside the operation knob 17a of the slider 15 of the flat portion 15a. The display unit 22a is turned on when it is determined that the LED lighting device checker 1 is normal (OK), and the display unit 22b is turned on when the LED lighting device checker 1 is defective (NG).

  Next to the display units 22a and 22b, selection switches 23a to 23c of the LED lighting device 12 are provided, and a reset switch 24 for resetting the microcomputer 14 is provided. The selection switches 23a to 23c include, for example, a display lamp that emits white light, and the types of the LED lighting devices 12 connected to the output end 11 of the variable current source 2 and the input end 4 that inputs the output of the LED lighting device 12. It is selected according to. Further, any one of the selection switches 23a to 23c is selected. The reset switch 24 has a display lamp that emits white light, for example.

  The LED type air traffic sign lights accommodate different types of LED lighting devices 12 according to the number of LED loads, light colors, and the like. In the present embodiment, as the LED lighting device 12, three types of model names LB1-9D, LU1-9D, and L1-8D manufactured by Toshiba Lighting & Technology Co., Ltd. are used.

  The LED lighting devices 12 of the model names LB1-9D and the model names LU1-9D receive the 6.6A, 5.2A, and 4.1A alternating currents output from the variable current source 2, respectively. Dimming and lighting at 100%, 25% and 5% of load. The LED lighting device 12 of model name LB1-9D is for one window and lights an LED load that emits green light, red light or yellow light, and the LED lighting device 12 of model name LU1-9D is for two windows. The LED load that emits green light, red light or yellow light is turned on.

  Further, the LED lighting device 12 of the model name L1-8D is lit at 100% for an LED load that emits green light or yellow light by inputting an alternating current of 6.6 A at the rated time and outputting a current of 0.66 A. In operation, an AC current of 4.8 A is input, a constant current of 42 mA is supplied to the LED load, and the LED load is turned on by 10%. In the LED lighting device 12 of the model name L1-8D, when an alternating current of 6.6 A is input, the display unit 20 a is turned on, and when an alternating current of 4.8 A is input, the display unit 20 c is turned on. Is.

  The display units 20a to 20c, the display units 21a and 21b, and the display units 22a and 22b form display means, and all are displayed using optical means such as LEDs. The display unit 20a and the display unit 21 display, for example, green, and the display units 20b and 21b display, for example, red.

  In addition, an opening / closing lid 25 is attached to the flat surface portion 15 c with a hinge 26 and a snap lock 27. The interior of the flat surface portion 15c of the main body portion 15 is a housing portion for a cable connecting the LED lighting device 12, the output end 11 and the input end 4, and the opening / closing lid 25 is opened and closed when the cable is taken out or stored. Is done.

  Hereinafter, the circuit configuration of the LED lighting device checker 1 will be described in detail with reference to FIGS. 4 and 5.

  In FIG. 4, a variable current source 2 as a current source includes a slidac 17, a step-down transformer 28, an ammeter 19 and the like, and includes a plug 29 inserted into an outlet (not shown) on the input side, and an output terminal on the output side. 11 output terminals 11a and 11b. The input side of the slidac 17 is connected to the plug 29 via the power switch 18, and the output side thereof is connected to the input side of the step-down transformer 28. The output side of the step-down transformer 28 is connected to the output terminals 11a and 11b.

  A current transformer 30 is connected between one output side of the step-down transformer 28 and the output terminal 11a. A current transformer 31 and a parallel circuit of current-limiting resistors R1 and R2 are connected in series between the other output side of the step-down transformer 28 and the output terminal 11b. An ammeter 19 is connected to the secondary side of the current transformer 30, and an input detection circuit 32 is connected to the secondary side of the current transformer 31.

  An external LED lighting device 12 is connected to the output terminals 11a and 11b. The LED lighting device 12 is formed by a known configuration for lighting an LED load (not shown). The LED lighting device 12 is formed so as to change the luminous intensity ratio of the LED load in accordance with the current value supplied from the output terminals 11a and 11b.

  A commercial AC power supply (AC 100 V) Vs is supplied to the outlet into which the plug 29 is inserted. When the plug 29 is inserted into the outlet and the power switch 18 is turned on, the commercial AC power supply Vs is applied to the slidac 17. AC current from the commercial AC power supply Vs is supplied. At this time, the ammeter 19 is operated with operating power supplied from the commercial AC power supply Vs.

  The slidac 17 is variable so that an alternating current corresponding to a plurality of luminous intensity ratios of the LED loads is output from the output terminals 11a and 11b. AC currents of 6.6 A, 5.2 A, and 4.1 A are output from the output terminals 11 a and 11 b for a plurality of luminous intensity ratios of 100%, 25%, and 5%. The slider 17 is varied so that the current value displayed on the ammeter 19 becomes the alternating current.

  When an alternating current is output from the output terminals 11a and 11b, a detection signal corresponding to the alternating current is input from the input detection circuit 32 to the microcomputer 14. Thus, the variable current source 2 has an output end 11 to which an external LED lighting device 12 is connected, and an AC current corresponding to a plurality of luminous intensity ratios of the LED load can be output from the output end 11. .

  The self-diagnosis power supply 3 includes an AC-DC adapter 33 and a DC-DC converter 34. The input side of the AC-DC adapter 33 is connected to the plug 29 via the power switch 18 and is formed so as to convert the commercial AC power supply (AC100V) Vs to the DC power supply (DC25V). The DC-DC converter 34 inputs the DC power output from the AC-DC adapter 33, outputs a DC current, and the output voltage is, for example, 12V.

  A display lamp 35 of the power switch 18 is connected between the outputs of the AC-DC adapter 33. The display lamp 35 displays the on / off state of the power switch 18. Thus, the self-diagnosis power supply 3 is configured to convert the input current of the variable current source 2 into a direct current and output it.

  Between the outputs of the self-diagnosis power supply 3, that is, between the outputs of the DC-DC converter 34, pseudo loads 5a to 5d, current adjusting resistors 13a to 13c, a current detecting resistor 36, current detecting circuits 37 and 38, and a photo The primary circuit 39a of the coupler 39 is connected by relays 40a and 40b and relays 41 to 45 forming the connection means 6. Further, the above-described configuration excluding the current detection resistors 13a to 13c is connected between the input terminals 4a and 4b of the input terminal 4 for inputting the output of the LED lighting device 12 by relays 40a and 40b and relays 41 to 45.

  As shown in FIG. 5, the relay circuits 46 to 51 and the switch circuits 52 to 57 for switching the relays 40 a and 40 b and the relays 41 to 45 form the connection means 6, and the AC-DC adapter 33 of the power supply 3 for self-diagnosis. It is connected between the positive electrode side and the microcomputer 14. When the operation power is supplied from the microcomputer 14 to the switch circuits 52 to 57, the switch circuits 52 to 57 energize (operate) the relay circuits 46 to 51, respectively. Thereby, each relay 40a, 40b and the relays 41-45 switch. Note that the switch circuits 52 to 57 are connected to the microcomputer 14 via a buffer without reference numerals (the same applies to the following switch circuits).

  The microcomputer 14 is operated by being supplied with operating power from the 5V power source 58. The 5V power source 58 is formed from the output voltage (DC 24V) of the AC-DC adapter 33 of the self-diagnosis power source 3. An operation monitor 59 and a switch circuit 60 are connected between the 5V power supply 58 and the microcomputer 14. When the microcomputer 14 operates, the operation monitor 59 is operated by supplying operation power to the switch circuit 60. The operation of the microcomputer 14 is confirmed by visual recognition of the operation monitor 60. Select switches 23a to 23c are connected between the 5V power supply 58 and the microcomputer 14.

  A reset switch 24 is connected between the negative electrode side of the AC-DC adapter 33 and the microcomputer 14. A display lamp 65 and display lamps 66a to 66c are connected between the positive electrode side of the AC-DC adapter 33 and the microcomputer 14 via switch circuits 61 to 64, respectively. The display lamp 65 is a display lamp of the reset switch 24, and the display lamps 66a to 66c are display lamps of the selection switches 23a to 23c.

  During standby, the microcomputer 14 outputs a high signal to the switch circuit 61 to turn on the display lamp 65. When the reset switch 24 is turned on instantaneously, a low signal is output to the switch circuit 61 to turn off the display lamp 65, and after the reset of the microcomputer 14, a high signal is output again to turn on the display lamp 65.

  Further, when the selection switches 23a to 23c are selected, the microcomputer 14 outputs a high signal to the corresponding switch circuits 62 to 64, and the display lamps 66a to 66c connected to the switch circuits 62 to 64. Lights up. Note that, when the operating power is supplied to the microcomputer 14, any one of the selection switches 23a to 23c, for example, the display lamp 66c is turned on.

  And between the positive electrode side of the AC-DC adapter 33 and the microcomputer 14, the evaluation results of the LED lighting device 12 are connected via the switch circuits 67 to 69 to which the display units 20 a to 20 c of the dimming tap are respectively connected. Via the switch circuits 70 and 71 to which the display units 21a and 21b are respectively connected, the switch circuits 72 and 73, the inverting circuit 74, the logical product ( An AND circuit 75, a logical product (AND) circuit 76, an upper limit level determination circuit 77, a lower limit level determination circuit 78, and an average value conversion circuit 79 are connected to each other.

  The microcomputer 14 controls the display units 20a to 20c to light up in accordance with the current value input from the input detection circuit 32. That is, when the output current of the variable current source 2 reaches the rated value of 6.6 A, the switch circuit 67 is operated to light the display unit 20a. When the output current of the variable current source 2 becomes 5.2 A, the switch circuit 68 is operated to turn on the display unit 20 b. When the output current becomes 4.1 A, the switch circuit 69 is operated to operate the display unit 20 c. Light up. Further, when the selection switch 23c is selected, when the output current becomes 4.8 A, the switch circuit 69 is operated to light the display unit 20c. Further, the microcomputer 14 controls the connecting means 6 as described later according to the current value input from the input detection circuit 32.

  When the microcomputer 14 determines that the evaluation result is normal in the inspection of the LED lighting device 12, the microcomputer 14 outputs a high signal to the switch circuit 70 to light the display unit 21a. If it is determined that the evaluation result is defective, a high signal is output to the switch circuit 71 to light the display unit 21b.

  When the microcomputer 14 determines that the evaluation result is normal in the self-diagnosis, the microcomputer 14 outputs a high signal to the AND circuit 75. Further, the microcomputer 14 always outputs an operation signal, for example, DC5V to the average value conversion circuit 79. The operation signals averaged by the average value conversion circuit 79 are input to an upper limit level determination circuit 77 and a lower limit level determination circuit 78, respectively. Then, the upper limit level determination circuit 77 determines that the operation signal is normal to a first predetermined value, for example, 3 V or more, and outputs a high signal, and the lower limit level determination circuit 78 outputs the operation signal to a second predetermined value, for example, If it is 1V or higher, it is judged normal and a high signal is output. When a high signal is output from the upper limit level determination circuit 77 and the lower limit level determination circuit 78, the logical product circuit 76 outputs a high signal to the logical product circuit 75.

  When the high signal from the evaluation result of the self-diagnosis is input while the high signal from the logical product circuit 76 is input, the logical product circuit 75 outputs the high signal to the switch circuit 72 and displays the display unit 22a. Light up. The logical product circuit 75 outputs a low signal when the high signal from the logical product circuit 76 is not input or when the high signal of the self-diagnosis evaluation result is not input. A high signal from the inverting circuit 74 is input to the switch circuit 73, and the display unit 22b is lit.

  The microcomputer 14 includes a CPU (Central Processing Unit) 80, a ROM (Read Only Memory) 81, and a RAM (Random Access Memory) 82. The CPU 80 performs various calculations based on a program stored in the ROM 81 and performs the above control. It is. Then, the switch circuits 52 to 57 are operated to connect the pseudo load 5 and the current detection means 7 between the outputs of the self-diagnosis power supply 3 or the input terminal 4 for inputting the output of the LED lighting device 12 by the connection means 6.

  In FIG. 4, the microcomputer 14 performs self-diagnosis when operating power is supplied from a 5V power source 58 and operates normally. First, the pseudo load 5a and the adjusting resistor 13a are connected between the outputs of the DC-DC converter 34 of the power supply 3 for self-diagnosis. That is, the microcomputer 14 supplies operating power to the switch circuits 52, 53, 55, 56 and 57. Thereby, each relay circuit 46, 47, 49, 50.51 operates, and relay 40a, 40b, 41, 43, 44, 45 switches, respectively.

  A DC current output from the DC-DC converter 34 flows through the pseudo load 5a. The current flowing through the pseudo load 5 a is detected by the current detection circuit 37 via the detection resistor 36. The current detected by the current detection circuit 37 is input to the primary circuit 39a of the photocoupler 39, and is input from the primary circuit 39a to the secondary circuit 39b of the photocoupler 39. Then, the average value of the current converted by the average value conversion circuit 82 and the peak value of the current converted by the peak value conversion circuit 83 are respectively input to the microcomputer 14.

  The CPU (central processing unit) 80 of the microcomputer 14 compares the average value of the current and the peak value with each reference value set in advance corresponding to the LED lighting device 12 of the model name LB1-9D, and the average value of the current And it is determined whether the crest value is within the range of each predetermined reference value. When it is determined that the current average value and the peak value are within the respective predetermined reference values, a high signal is output to the AND circuit 75 for a predetermined period, for example, 4 to 6 seconds. As a result, a high signal is output from the logical product circuit 75 to the switch circuit 72, the self-diagnosis display unit 22a is lit for a predetermined period, and normality (OK) is notified. If it is determined that the average value and the peak value of the current are not within the range of the respective predetermined reference values, no high signal is output for a predetermined period. As a result, a high signal is output from the inverting circuit 74 to the switch circuit 73, the self-diagnosis display unit 22b is lit for a predetermined period, and a failure (NG) is reported.

  The reference value is not limited to be written in the program, but may be stored in the ROM 81 and read from the ROM 81, for example.

  The microcomputer 14 automatically resets after the elapse of the predetermined period, and connects the pseudo load 5 b and the adjusting resistor 13 b between the outputs of the DC-DC converter 34. That is, the microcomputer 14 supplies operating power to the switch circuits 52, 55, and 57. Thereby, each relay circuit 46,49,51 operate | moves and each relay 40a, 40b, 43, 45 switches.

  Then, as described above, the average value and the peak value of the current flowing through the pseudo load 5b are compared with the respective reference values set in advance corresponding to the LED lighting devices 12 of the model name LU1-9D. It is determined whether or not the peak value is within the range of each predetermined reference value. When it is determined that the current average value and the peak value are within the respective predetermined reference values, the self-diagnosis display unit 22a is lit for a predetermined period, and the current average value and the peak value are If it is determined that it is not within the range of the respective predetermined reference values, the self-diagnosis display unit 22b is lit for a predetermined period.

  Next, the microcomputer 14 connects the pseudo load 5 c and the adjustment resistor 13 b between the outputs of the DC-DC converter 34. That is, the microcomputer 14 supplies operating power to the switch circuits 64, 55, and 57. As a result, the relay circuits 48, 49, 51 are operated, and the relays 42, 43, 45 are switched.

  The current flowing through the pseudo load 5 c is detected by the current detection circuit 38 and input to the photocoupler 39, converted into an average value by the average value conversion circuit 82, and converted into a peak value by the peak value conversion circuit 83.

  As described above, the average value and the crest value of the current flowing through the pseudo load 5c are the respective reference values set in advance corresponding to the rated time of the LED lighting device 12 of the model name L1-8D in the microcomputer 14. A comparison is made to determine whether or not each is within the range of each predetermined reference value. When it is determined that the current average value and the peak value are within the respective predetermined reference values, the self-diagnosis display unit 22a is lit for a predetermined period, and the current average value and the peak value are If it is determined that it is not within the range of the respective predetermined reference values, the self-diagnosis display unit 22b is lit for a predetermined period.

  Next, the microcomputer 14 connects the pseudo load 5 d and the adjusting resistor 13 c between the outputs of the DC-DC converter 34. That is, the microcomputer 14 supplies operating power to the switch circuit 55. Thereby, the relay circuit 51 operates and the relay 43 is switched. The current flowing through the pseudo load 5 d is detected by the current detection circuit 38 and input to the photocoupler 39, converted into an average value by the average value conversion circuit 82, and converted into a peak value by the peak value conversion circuit 83.

  In the microcomputer 14, the average value and the peak value of the current flowing through the pseudo load 5d are compared with respective reference values set in advance corresponding to the operation of the LED lighting device 12 of the model name L1-8D. It is determined whether or not the average value and the peak value are within the respective predetermined reference values. When it is determined that the current average value and the peak value are within the respective predetermined reference values, the self-diagnosis display unit 22a is lit for a predetermined period, and the current average value and the peak value are If it is determined that it is not within the range of the respective predetermined reference values, the self-diagnosis display unit 22b is lit for a predetermined period.

  As described above, the microcomputer 14 including the evaluation unit 8 and the control unit 10 sequentially controls the connection unit 6, the current detection unit 7, and the display unit 9, and compares the current flowing through the pseudo load 5 with a preset reference value. The LED lighting device checker 1 is configured to perform self-diagnosis as to whether or not the different types of LED lighting devices 12 can be normally inspected. The control unit 10 may be provided in each of the connection unit 6, the current detection unit 7, the evaluation unit 8, and the display unit 9.

  Next, the operation of this embodiment will be described.

  When the power switch 18 is turned on and an input current is input from the commercial AC power supply Vs to the variable current source 2, power is supplied from the self-diagnosis power supply 3 to the 5V power supply 58. Then, operating power is supplied from the 5V power source 58 to the microcomputer 14 to operate the microcomputer 14.

  The microcomputer 14 outputs an operation signal to the average value conversion circuit 79 during operation. If the operation signal is within the normal range, a high signal indicating that the microcomputer 14 is operating normally is output from the AND circuit 76 to the AND circuit 75.

  When the microcomputer 14 operates in the initial stage, the pseudo load 5 a is connected between the outputs of the DC-DC converter 34 of the self-diagnosis power supply 3. And the average value and peak value of the electric current which flow through the pseudo load 5a are compared with each reference value preset corresponding to the LED lighting device 12 of model name LB1-9D. If the average current value and the peak value are within the range of the respective reference values, the display unit 22a indicating normal (OK) is turned on, and the average value and peak value of the current are outside the range of the respective reference values. If there is, the display unit 22b indicating failure (NG) is turned on. Each of the display unit 22a and the display unit 22b is turned on for a predetermined period, for example, 4 to 6 seconds. By checking the lighting of the display unit 22a and the display unit 22b, it can be confirmed whether or not the LED lighting device checker 1 can normally inspect the LED lighting device 12 of the model name LB1-9D.

  Next, the microcomputer 14 connects the pseudo load 5b between the outputs of the DC-DC converter 34, and the average value and the peak value of the current flowing through the pseudo load 5b correspond to the LED lighting device 12 of the model name LU1-9D. It compares with each preset reference value. In the same manner as described above, the display unit 22a or the display unit 22b is turned on for a predetermined period. Thereby, it can be confirmed whether the LED lighting device checker 1 can normally inspect the LED lighting device 12 of the model name LU1-9D.

  Next, the microcomputer 14 connects the pseudo load 5c between the outputs of the DC-DC converter 34, and responds to the average value and peak value of the current flowing through the pseudo load 5c when the LED lighting device 12 of the model name L1-80 is rated. Then, it compares with each preset reference value. In the same manner as described above, the display unit 22a or the display unit 22b is turned on for a predetermined period. Thereby, it can be confirmed whether the LED lighting device checker 1 can normally perform the inspection at the time of rating of the LED lighting device 12 of the model name L1-80.

  Next, the microcomputer 14 connects the pseudo load 5d between the outputs of the DC-DC converter 34, and copes with the average value and peak value of the current flowing through the pseudo load 5d when operating the LED lighting device 12 of the model name L1-80. Then, it compares with each preset reference value. In the same manner as described above, the display unit 22a or the display unit 22b is turned on for a predetermined period. Thereby, it can be confirmed whether the LED lighting device checker 1 can normally perform the inspection during the operation of the LED lighting device 12 of the model name L1-80.

  In this way, the LED lighting device checker 1 can easily check its own normal operation, whereby the different types of LED lighting devices 12 can be normally inspected.

  When the LED lighting device 12 is inspected, the LED lighting device 12 is connected to the output terminal 11 of the constant current source and the input terminal 4 for inputting the output of the LED lighting device 12 by a cable. In the case of the LED lighting device 12 having the model name LB1-90, the selection switch 23a is instantly turned on. The microcomputer 14 supplies operating power to the switch circuits 52 and 53 to operate the relay circuits 46 and 47. As a result, the relays 40a, 40b, and 41 are switched, and the pseudo load 5a is connected between the input terminals 4a and 4b of the input terminal 4 that inputs the output of the LED lighting device 12.

  In the case of the LED lighting device 12 having the model name LU1-90, after the reset switch 24 is turned on, the selection switch 23b is turned on instantaneously. The microcomputer 14 supplies operating power to the switch circuit 52 to operate the relay circuit 47. As a result, the relays 40 a and 40 b are switched, and the pseudo load 5 b is connected between the input terminals 4 a and 4 b of the input terminal 4 of the LED lighting device 12.

  In the case of the LED lighting device 12 having the model name L1-80, after the reset switch 24 is turned on, the selection switch 23c is turned on instantaneously. The microcomputer 14 switches the relay 42 according to the current value input from the input detection circuit 32. That is, by changing the slidac 17, when the current value displayed on the ammeter 19 becomes 6.6 A at the rated time (tap 5, luminous intensity ratio 100%), operating power is supplied to the switch circuit 54 to provide a relay circuit. 48 is operated. As a result, the relay 42 is switched and the pseudo load 5 c is connected between the input terminals 4 a and 4 b of the input terminal 4. At this time, the indicator lamp 20a is turned on. Further, when the current value displayed on the ammeter 19 becomes 4.8 A during operation (tap 3, luminous intensity ratio 10%), operating power is not supplied to the switch circuit 54. Thereby, the pseudo load 5 d is connected between the input terminals 4 a and 4 b of the input terminal 4. At this time, the indicator lamp 20c is turned on.

  In addition, when inspecting the LED lighting device 12 of the model name LB1-90 and the model name LU1-90, the input current input to the LED lighting device 12 is sequentially 6.6A (tap 5, luminous intensity ratio 100%). 2A (tap 4, luminous intensity ratio 25%) and 4.1 A (tap 3, luminous intensity ratio 5%). At this time, the slider 17 is varied so that the current flowing through the ammeter 19 becomes the input current. And when it becomes the said electric current, the indicator lamps 20a-20c corresponding to the said electric current will be lighted.

  The microcomputer 14 compares the average value and the peak value of the current flowing through the pseudo loads 5 a to 5 d with each inspection reference value set in advance corresponding to the LED lighting device 12. If the average value and peak value of the current are within the range of the respective inspection reference values, the display unit 21a indicating normal (OK) is turned on, and the average value and peak value of the current are the respective reference reference values for inspection. If it is out of the range, the display unit 21b indicating a failure (NG) is turned on. By checking the lighting of the display unit 21a and the display unit 21b, it can be confirmed whether or not the LED lighting device 12 operates normally.

  The inspection reference value may be written in a program, for example, stored in the ROM 81.

  According to this embodiment, the pseudo load 5 is connected between the outputs of the power supply 3 for self-diagnosis, and the current flowing through the pseudo load 5 is compared with a reference value set in advance corresponding to the LED lighting device 12 for evaluation. Since the evaluation results are displayed on the self-diagnosis display units 22a and 22b, it can be confirmed that the LED lighting device checker 1 operates normally and the LED lighting device 12 can be normally inspected. There is an effect that the reliability of the inspection result of the apparatus 12 can be improved.

  Further, even if there is a defective (NG) pseudo load 5, the LED lighting device 12 corresponding to the normal pseudo load 5 can be inspected.

  Further, the microcomputer 14 composed of the evaluation means U and the control means 10 causes the connecting means 6 to connect the pseudo load 5 between the outputs of the self-diagnosis power supply 3 when the input current is input to the variable current source 2 from the commercial AC power supply Vs. Since a series of control operations by the current detection means 7 and the display means 9 are performed, the self-diagnosis of whether or not the LED lighting device checker 1 is operating normally can be facilitated.

  The plurality of pseudo loads 5a to 5d provided corresponding to the types of the LED lighting devices 12 are for current adjustment so that the currents detected by the current detection circuits 37 and 38 of the current detection means 7 are substantially constant. Since it is connected between the outputs of the power supply 3 for self-diagnosis via the resistors 13a to 13c, the number of reference values respectively compared with the average value and peak value of the current flowing through the pseudo load 5 can be minimized. Thus, it is possible to reduce the burden of the arithmetic processing in the microcomputer 14 and to perform the arithmetic processing quickly.

  In addition, this invention is not limited to the structure of the said embodiment, A various deformation | transformation is possible in the range which does not deviate from the summary of invention.

DESCRIPTION OF SYMBOLS 1 ... LED lighting device checker, 2 ... Variable current source as current source, 3 ... Self-diagnosis power supply, 4 ... Input end, 5 ... Pseudo load, 6 ... Connection means, 7 ... Current detection means, 8 ... Evaluation means , 9 ... Display means, 11 ... Output terminal, 13 ... Current adjustment resistor

Claims (4)

A current source having an output terminal to which the LED lighting device is connected and configured to output a current from the output terminal;
A power supply for self-diagnosis configured to output direct current;
An input terminal for inputting an output of the LED lighting device;
Pseudo load;
Connecting means for connecting the pseudo load to the input terminal when the LED lighting device is inspected, and connecting the pseudo load between outputs of the self-diagnosis power source during self-diagnosis;
Current detection means for detecting a current flowing through the pseudo load;
Evaluation means for comparing and evaluating the current detected by the current detection means and a preset reference value;
Display means for displaying the evaluation result of the evaluation means;
The checker for LED lighting devices characterized by comprising. A current source capable of supplying a current to the LED lighting device to be inspected;
A power supply for self-diagnosis capable of outputting DC current;
A pseudo load fed from the current source or the power supply for self-diagnosis;
An evaluation means for comparing and evaluating the current flowing through the pseudo load and a preset reference value;
Display means for displaying the evaluation result of the evaluation means;
And supplying the pseudo load from the current source via the LED lighting device when inspecting the LED lighting device, and supplying power to the pseudo load from the self-diagnosis power source during self-diagnosis. An LED lighting device checker characterized in that the evaluation result is obtained.   The pseudo load consists of a plurality provided corresponding to the type of the LED lighting device, and is fed from the power supply for self-diagnosis via a current adjusting resistor so that the current flowing through the pseudo load is substantially constant. The LED lighting device checker according to claim 1, wherein the checker is an LED lighting device checker.   When an input current is input to the current source, the pseudo load is fed from the power supply for self-diagnosis, and the current flowing through the pseudo load is compared with a preset reference value for evaluation, and the evaluation result The LED lighting device checker according to any one of claims 1 to 3, wherein a series of operations for displaying is automatically performed.

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