KR102350618B1 - Integrated inspection device for LED module - Google Patents

Abstract

An integrated LED module inspection device is provided. The integrated LED module inspection device is to inspect a common cathode LED module in which a plurality of parallel LED lines are branched from a common cathode node, or a common anode LED module in which a plurality of parallel LED lines are branched from a common anode node, connected between power and ground. The inspection device includes an independent driving unit which is selectively disposed between the power source and any one of the parallel LED lines of the common cathode LED module, or between any one of the parallel LED lines of the common anode LED modules and the ground, and drives the LED. The independent driving unit includes: a main line which has both ends respectively connected to the power source and the anode of any one parallel LED line of the common cathode LED modules according to the arrangement of the independent driving unit, or both ends respectively connected to the anode of any one of the common cathode LED modules and the ground to conduct both ends; a constant current control unit which controls the current of the main line; and an insulated power supply unit which provides operating power applied to the constant current control unit but is insulated so as not to share a reference potential with the ground.

Description

Integrated inspection device for LED module

The present invention relates to an LED module inspection apparatus, and more particularly, to an integrated LED module inspection apparatus capable of inspecting two or more structurally different LED modules.

Light sources used in the past are being replaced with LEDs. LED (Light Emitting Diode) has already been developed in the second half of the 20th century, but there are problems in securing appropriate optical properties (illuminance, luminance, etc.) and color realization (white light source), so it was not immediately used as a light source. With continuous technology development, many parts have been improved now that we enter the 21st century, and LED light sources have become more common due to another advantage of consuming less power.

Since the LED itself is a small semiconductor device, it can be used in combination in various forms as needed. For example, illuminance and luminance may be enhanced by arranging a plurality of LEDs in an array, and LEDs of different colors may be bundled into modules to adjust emission colors. Alternatively, non-standardized various types of modules are being manufactured. These LED products are inspected in various ways to see whether they operate normally before shipment (eg, Korean Patent 10-0957748, etc.).

However, as various types of products were produced, there was a problem that it was difficult to smoothly conduct pre-shipment inspections. For example, in the case of products composed of LED modules, the structure of the module may not be uniform, and accordingly, there is a problem that different inspection methods or inspection devices have to be used for different structures. Since these problems are unreasonable, such as setbacks in product production and making it difficult for manufacturers to handle various products, improvement is required.

Republic of Korea Patent Publication No. 10-0957748, (2010. 05. 13)

The technical problem of the present invention is to solve this problem, and to provide an integrated LED module inspection device capable of inspecting two or more structurally different LED modules.

The technical problem of the present invention is not necessarily limited to the above-mentioned problems, and another technical problem not mentioned will be clearly understood by those skilled in the art from the following description.

The integrated LED module inspection apparatus according to the present invention has a common cathode node connected between a power source and ground, and a common cathode LED module including a plurality of parallel LED lines branched from the common cathode node, or a common anode node, In the integrated LED module inspection device for inspecting a common anode LED module including a plurality of parallel LED lines branched from a common anode node, the integrated LED module inspection device, any one of the power supply and the common cathode LED module At least one independent driving unit selectively disposed between the parallel LED lines or between the parallel LED line of any one of the common anode LED modules and the ground to independently drive the LEDs of each parallel LED line, the independent The driving unit has both ends respectively connected to the power source and the anode of the parallel LED line of any one of the common cathode LED modules according to the arrangement of the independent drive unit, or both ends are each connected to the anode of any one of the common cathode LED modules a cathode of the parallel LED line and a main line connected to the ground to conduct both ends; a constant current control unit including a constant current control circuit disposed on the main line to control the current of the main line; and an insulated power supply unit that provides operating power applied to the constant current control unit and is insulated so as not to share a reference potential with the ground.

The integrated LED module inspection device is selectively connected to any one of the parallel LED lines of the common cathode LED module, or the parallel LED line of any one of the common cathode LED modules according to the arrangement of the independent driving unit to increase the voltage It may further include at least one voltage measuring unit for measuring.

The voltage measuring unit is switched according to the connection position of the main line, and the voltage measuring unit is connected between the anode of the parallel LED line of any one of the common cathode LED modules and the ground, or between the power supply and the common cathode LED module. It may include a switching circuit for connecting in parallel between the cathodes of any one of the parallel LED lines.

The insulated power supply unit may include a secondary circuit of a second insulated converter in which the primary circuit and the secondary circuit are electrically insulated.

The constant current control unit may include a current detection circuit disposed at a rear end of the constant current control circuit on the main line, and a current measurement value of the current detection circuit between the current detection circuit and the constant current control circuit, and the current measurement value Accordingly, it may further include a central control module for feedback control of the constant current control circuit.

The constant current control circuit includes a bipolar transistor having a base end connected to the central control module side and an emitter and collector end connected on the main line, and the constant current control unit is disposed between the central control module and the base end. It may further include a digital to analog (DA) signal converter disposed, and an analog to digital (AD) signal converter disposed between the current detection circuit and the central control module.

The independent driving unit may further include an insulated communication unit that receives an external control signal and applies it to the constant current control unit, but is electrically insulated from the outside.

The insulated communication unit may be formed to include a secondary-side circuit of a second insulated converter in which the primary-side circuit and the secondary-side circuit are electrically insulated.

A plurality of the independent driving units are arranged in parallel between the power source and each of the plurality of parallel LED lines of the common cathode LED module to form a first parallel driving circuit, or a plurality of the plurality of common cathode LED modules A second parallel driving circuit may be formed by being disposed in parallel between each of the parallel LED lines and the ground, wherein the second parallel driving circuit may include a connection line connecting the insulated power supply unit and the ground to match a reference potential. .

According to the present invention, it is possible to inspect all LED modules having different structures using one inspection device. In particular, since different LED modules, which had to be inspected with completely different devices in the prior art, can be integrated and inspected into one inspection device, resulting in a complex synergistic effect of lowering product inspection costs and increasing productivity. The present invention can be applied to various types of products composed of a plurality of LEDs in a module form, and is very useful because, for example, LED products such as a direction indicator lamp for automobiles that have been recently developed can be smoothly inspected. In addition, through a structure that excludes the use of a high-speed switching device such as a conventional MOSFET or a boost circuit, ripple noise generated during inspection is substantially removed, and inspection through fine current control can be performed very smoothly.

1 is a block diagram showing the configuration of an independent driving unit of an integrated LED module inspection device according to an embodiment of the present invention.
FIG. 2 is a configuration diagram illustrating an example in which the independent driving unit of FIG. 1 is applied to a common cathode LED module.
3 is a configuration diagram illustrating an example in which the independent driving unit of FIG. 1 is applied to a common anode LED module.
4 is a view illustrating the use state of the integrated LED module inspection device according to an embodiment of the present invention including the independent driving unit and the voltage measuring unit of FIG. 1 .
5 is a view showing different inspection devices and common cathode LED module and common anode LED module applied to each of the conventional common cathode LED module and common anode LED module.

Advantages and features of the present invention and methods for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete and common knowledge in the art to which the present invention pertains. It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the claims. Like reference numerals refer to like elements throughout.

Hereinafter, an integrated LED module inspection apparatus according to the present invention will be described in detail with reference to FIGS. 1 to 5 .

1 is a block diagram illustrating the configuration of an independent driving unit of an integrated LED module inspection device according to an embodiment of the present invention, and FIG. 2 is a configuration showing an example of applying the independent driving unit of FIG. 1 to a common cathode LED module 3 is a block diagram illustrating an example of applying the independent driving unit of FIG. 1 to a common anode LED module.

1 to 3, the integrated LED module inspection apparatus (see 1 in FIG. 4) according to the present invention is both a common cathode LED module (refer to 2A in FIG. 2) and a common anode LED module (refer to 2B in FIG. 3) formed to be inspected. As will be described later, the common cathode LED module 2A and the common anode LED module 2B have different structures, so different types of inspection equipment are used, which makes it difficult to handle different LED modules at the production site, It increased the inspection time and caused economic loss as a result. In particular, in the past, it was known that it was difficult to configure a circuit capable of illuminating all of them due to the structural difference between the common cathode LED module 2A and the common anode LED module 2B, but the present invention provides a common cathode LED module 2A and a common cathode LED module 2A This problem is solved by using the independent driving unit 10 applicable to either of the anode LED modules 2B. That is, the integrated LED module inspection device 1 of the present invention is, as shown in FIGS. 2 to 3, a common cathode LED module 2A, or a common anode LED module 2B, either parallel LED lines 2A2, 2B2. It has a feature including an independent driving unit 10 for smoothly driving.

The integrated LED module inspection device 1 of the present invention is specifically configured as follows. The integrated LED module inspection device 1 has a common cathode node 2A1, connected between the power source C and the ground D, as shown in FIGS. 2 and 3, and a plurality of branches branched from the common cathode node 2A1 A common cathode LED module 2A including a parallel LED line 2A2 of In the integrated LED module inspection device (1) for inspecting the module (2B), the integrated LED module inspection device (1), the parallel LED line (2A2) of any one of the power supply (C) and the common cathode LED module (2A) ), or at least one selectively disposed between the parallel LED line 2B2 and the ground D of any one of the common anode LED modules 2B to independently drive the LEDs of each parallel LED line 2A2, 2B2 of an independent drive unit (see 10 in FIG. 1), and the independent drive unit 10 has a power supply C and a common cathode LED module 2A at both ends according to the arrangement of the independent drive unit 10, respectively. Either one of the parallel LED lines 2A2 is connected to the anode [Fig. 2], or both ends are respectively connected to the cathode and the ground D of any one of the parallel LED lines 2B2 of the common anode LED module 2B. [FIG. 3] A constant current control unit ( 120), and an insulated power supply unit (refer to 131 in FIG. 1) that provides operating power applied to the constant current control unit 120 but is insulated so as not to share a reference potential with the ground (D).

In one embodiment of the present invention, the integrated LED module inspection device (1), according to the arrangement of the independent driving unit (10), any one of the parallel LED line (2A2) of the common cathode LED module (2A), or the common anode LED The module (2B) further includes a voltage measuring unit (refer to 20 in FIG. 4) that is selectively connected to the parallel LED line (2B2) of any one of the modules (2B) to measure the voltage, the voltage measuring unit 20 is the main line (110) ) between the anode and the ground (D) of the parallel LED line (2A2) of any one of the common cathode LED modules (2A) by switching the voltage measuring unit 20 (Fig. 4(a)), or a switching circuit (refer to 23 in FIG. 4) for connecting in parallel between the power supply C and the cathode of the parallel LED line 2B2 of the common anode LED module 2B (see FIG. 4(b)) can do. Hereinafter, the configuration and effect of the present invention will be described in more detail based on one embodiment of the present invention. First, the description proceeds in detail with respect to the independent driving unit 10 , and then, based on this, the description of the voltage measuring unit 20 is performed.

5 is a view showing different inspection devices and common cathode LED module and common anode LED module applied to each of the conventional common cathode LED module and common anode LED module.

Before describing the independent driving unit 10, briefly describe the structure and problems during inspection of the common cathode LED module 2A and the common anode LED module 2B, which are the inspection objects of the present invention, with reference to FIG. 5 for a moment. . As shown in the enlarged view of FIG. 5, the common cathode LED module 2A and the common anode LED module 2B are formed by connecting LED elements in series and parallel, but have different structures. The common cathode LED module 2A includes a plurality of parallel LED lines 2A2 having a common cathode node 2A1 and branched from the common cathode node 2A1 as shown in the enlarged view of FIG. 5A. At least one LED element (a) is arranged on each parallel LED line (2A2), and in the case of a plurality of LED elements (a), the LED element (a) is arranged in series on each parallel LED line (2A2). Due to this structure, the end of each parallel LED line 2A2 opposite to the common cathode node 2A1 becomes an anode. On the other hand, the common anode LED module 2B has a common anode node 2B1 as shown in the enlarged view of FIG. 5(b) and includes a plurality of parallel LED lines 2B2 branched from the common anode node 2B1. do. At least one LED element a is also arranged on each parallel LED line 2B2, and in the case of a plurality of LED elements a, the LED element a is arranged in series on each parallel LED line 2B2. Due to this structure, the ends of each parallel LED line 2B2 opposite the common anode node 2B1 are all cathodes. The LED module having such a structure is not necessarily limited thereto, but may be used, for example, as a direction indicator lamp for a vehicle.

Conventional common cathode LED module (2A) is a common cathode LED module (2A) dedicated inspection device (G) as exemplified in FIG. bite and tested. In addition, the common anode LED module (2B) is a common anode LED module (2B) dedicated inspection device (H) as illustrated in FIG. It was tested by biting on the cathode. Each dedicated inspection device (G, H) could not be used to inspect one another because the connection location between the power source (C) and the ground (D) and the corresponding internal structure were different, and it was difficult to graft or merge them. For example, if the inspection device (G) dedicated to the common cathode LED module (2A) is connected to the location of the inspection device (H) dedicated to the common anode LED module (2B), the circuit is crossed and an error occurs in detecting the current on the LED side and malfunctions. There was a problem that the common anode LED module (2B) dedicated inspection device (H) is connected to the position of the common cathode LED module (2A) dedicated inspection device (G), there was a problem that the LED module itself is not driven. Therefore, it was impossible to simply change the positions of each other and use them. In addition, in the case of the inspection device (G) dedicated to the common cathode LED module (2A), a high-speed switching device such as a MOSFET or a boost circuit using the same is often used, so there is also a problem in that the generation of current ripple is not free. Conventionally, each inspection device (G, H) is shared between the power source (C) and the ground (D) and the power source (C) according to the structure of the common cathode LED module (2A) or the common anode LED module (2B). It was designed to form an integrated circuit (hence a common ground).

Referring to Figure 1, the integrated LED module inspection device of the present invention, as described above, a parallel LED line ( 2A2) or between the parallel LED line 2B2 of any one of the common anode LED modules (see 2B in FIG. 3) and the ground D, the LEDs of each parallel LED line 2A2 and 2B2 are independent It includes at least one independent driving unit (10) for driving. That is, the independent driving unit 10 of the present invention is applicable to either the common cathode LED module 2A or the common anode LED module 2B. Since the number of parallel LED lines 2A2 and 2B2 of each LED module can be increased or decreased as needed, independent driving units 10 corresponding to the number can be formed. In particular, the independent driving unit 10 of the present invention includes an insulated power supply unit 131 that is insulated so as not to share a reference potential with the ground (D) shown in each figure, and an insulated communication unit 132 electrically insulated from the outside. ) may be included. Fig. 1 (a) is a more simplified view of the independent driving unit 10, and the corresponding detailed configuration is specifically shown in Fig. 1 (b). The structure of the independent driving unit 10 will be described in more detail with reference to FIG. 1B as follows.

The independent driving unit 10 includes a main line 110 for transporting the lighting current of the common cathode LED module 2A or the common anode LED module 2B. Both ends of the main line 110 are connected to the anode of the parallel LED line 2A2 of any one of the power supply C and the common cathode LED module 2A depending on the arrangement of the independent driving unit 10 [FIG. 2] , or both ends are connected to the cathode of the parallel LED line 2B2 of any one of the common anode LED modules 2B and the ground D [FIG. 3] to energize both ends. The main line 110 may be formed using, for example, one or more than one wiring, and the physical shape and the like do not need to be particularly limited as long as such an operation is possible. For example, both ends of the main line 110 are formed of connection terminals, etc., and may be selectively connected to other lines and the like. As the main line 110, one having an appropriate allowable current may be used in consideration of the amount of current that can be conducted.

A constant current control circuit 121 is disposed on the main line 110 as shown in FIG. A constant current control unit 120 to control is formed. Specifically, the constant current control unit 120 includes a current detection circuit 122 disposed at the rear end of the constant current control circuit 121 on the main line 110 , and a current detection circuit between the current detection circuit 122 and the constant current control circuit 121 . It may include a central control module 123 that receives the current measurement value of 122 and feedback-controls the constant current control circuit 121 according to the current measurement value. Such a current control circuit may be a control circuit mixed with a kind of analog method that excludes a high-speed switching element such as a MOSFET or a booster circuit including the same. It is possible to control the current (eg, a very small lighting current of several to several tens of μA). More specifically, the constant current control circuit 121 includes a bipolar transistor 121a whose base end is connected to the central control module 123 side and whose emitter and collector ends are connected on the main line 110, The constant current control unit 120 is disposed between the central control module 123 and the DA (Digital to Analog) signal converter 124 disposed between the base end, and the current detection circuit 122 and the central control module 123 . It may be formed in a form including an analog to digital (AD) signal converter 125 .

That is, when the current value of the main line 110 is detected by the current detection circuit 122 and input to the central control module 123 through the AD signal converter 125, the central control module 123 is an insulated communication unit ( A kind of feedback signal that matches the current value of the control signal transmitted from 132) can be applied to the constant current control circuit 121 through the DA signal converter 124, and through this, the current value of the main line 110 is continuously adjusted can In this way, the above-described minimum lighting current control and the like are also possible. For example, the central control module 123 may be formed of a microcontroller unit (MCU) including a central processing unit, etc., a constant current control circuit 121, a current detection circuit 122, a DA signal converter 124, In the AD signal converter 125, for example, elements necessary for signal stabilization, amplification, etc. may be additionally disposed. The current detection circuit 122 may be formed of, for example, an ammeter including a resistor connected in series on the main line 110 . The independent driving unit 10 may be configured in a form in which the main line 110 and the constant current control unit 120 including such a configuration are connected to each other.

The independent driving unit 10 provides operating power applied to the constant current control unit 120 as described above, but is insulated so as not to share a reference potential with the ground (refer to D of FIGS. 2 to 4) of the entire test circuit. It includes a power supply 131 . In addition, it receives the external control signal and applies it to the constant current control unit 120 (in particular, toward the central control module described above), but includes an insulated communication unit 132 electrically insulated from the outside. These are components that form the insulating structure of the independent driving unit 10, and are collectively indicated as an insulating operation unit 130 in FIGS. 1 (a) and (b). Due to the insulating structure of the insulating operation unit 130, the independent driving unit 10 is applicable to both the common cathode LED module 2A and the common anode LED module 2B. For example, the insulated power supply unit 131 may be formed including the secondary side circuit 131a of the first insulating converter 141 in which the primary side circuit 141a and the secondary side circuit 131a are electrically insulated. , the insulated communication unit 132 may be formed to include a secondary-side circuit 132a of the second insulating converter 142 in which the primary-side circuit 142a and the secondary-side circuit 132a are electrically insulated.

The first insulating converter 141 and the second insulating converter 142 may have different capacities from each other, but both use an insulating circuit structure such as a fully insulated coil, and an independent driving unit such as an external power source (C') or an external communication line (10) It is possible to form a structure in which internal components are not directly energized. That is, the insulated power supply unit 131 and the insulated communication unit 132 may be formed by using an insulating circuit structure capable of converting and transmitting current or voltage from the primary side to the secondary side in an insulated state or transmitting an electrical signal. At this time, the insulation circuit structure of each insulation converter is not necessarily limited to a structure such as an insulated coil. It is also possible In the case of the second insulating converter 142 corresponding to the communication circuit, such a structure may be possible. In addition, if there are other possible insulated circuit structures, such structures may be used. However, in the present embodiment, it is not necessary to be limited thereto, but an insulated circuit structure including a coil in which the primary side and the secondary side are insulated will be exemplarily described. For example, the primary side circuit 141a and the secondary side circuit 131a of the first insulating converter 141 may be formed of a primary side coil and a secondary side coil electrically insulated from each other, and the second insulating converter 142 . The primary side circuit 142a and the secondary side circuit 132a may be formed of a primary side coil and a secondary side coil electrically insulated from each other. Due to this insulating structure, an insulated power source ground 150 having a different reference potential from the above-described ground D may be formed in the independent driving unit 10 by itself. The insulated power ground 150, 151, 152, 153 shown on each of the drawings of FIGS. 1 to 3 is for revealing the insulation structure of the independent driving unit 10 on the entire circuit, and may be different from the general circuit symbol. can

That is, the independent driving unit 10 is insulated from the external power source C' and the external communication line, and may receive power or receive an external control signal by using an insulating circuit structure such as a coil. The external power source C′ shown in FIG. 1B may be the same as the power source C of FIGS. 2 to 4 , or may be a different power source depending on circumstances. As described above, in a state insulated from the external power source C′, power may be provided to the insulated power supply unit 131 using, for example, an electromagnetic induction action between coils, or a control signal may be applied to the insulated communication unit 132 . The insulated power supply unit 131 may be formed to include an element capable of storing power in addition to the secondary side circuit 131a, and the insulated communication unit 132 is a signal processing circuit ( 132b) and the like. The primary side circuit 142a (ie, the primary side coil of the second insulating converter) corresponding to the secondary side circuit 132a of the insulated communication unit 132 may be connected to an external communication line.

As shown in FIGS. 2 and 3 , the independent driving unit 10 is connected to the common cathode LED module 2A or the common anode LED module 2B to form a circuit capable of inspecting both sides. . First, referring to FIG. 2 , a circuit capable of inspecting the common cathode LED module 2A may be configured as follows. One independent driving unit 10 is disposed between the power supply C and the parallel LED line 2A2 of any one of the common cathode LED module 2A. The independent driving unit 10 may be arranged as many as the number of parallel LED lines 2A2 as described above. In the drawing, a common cathode LED module 2A having three parallel LED lines 2A2 is shown, and accordingly, an inspection circuit in which three corresponding independent driving units 10 are disposed is shown, but the number can be any number as needed. can be increased. Different independent driving units 10 are connected in parallel to independently drive the corresponding parallel LED lines 2A2, which are indicated by different channels (eg, CH1, CH2, CH3). That is, the independent driving unit 10, as described above, is the power supply (C) of the entire inspection circuit by the insulating operation unit 130 such as an insulated power supply unit (see 131 in FIG. 1), an insulating communication unit (see 132 in FIG. 1), etc. ) and the ground (D) and the insulated power structure, and thus the insulated power ground (151, 152, 153) having a different reference potential from the ground (D) of the test circuit can be formed. The insulated power ground 151 , 152 , and 153 of each independent driving unit 10 may have different reference potentials from each other. The inspection circuit can receive control signals from the operation unit (E), which can operate such as setting control signals, and the external control unit (F) connected to the operation unit (E), and the external communication lines for transmitting the control signals are each independently driven Insulation from the unit 10 is the same as described above.

With such a circuit configuration, a lighting current can flow in each parallel LED line 2A2 of the common cathode LED module 2A by using the main line 110 of each of the independent driving units 10 connected in parallel. Each independent driving unit 10 receives the operating power of the internal circuit from the insulated power supply unit 131 insulated from the outside, and the control signal is also applied through the insulated communication unit 132 insulated from the external communication line. The remaining parts other than the line 110 may be viewed in an insulated state. Therefore, it is possible to smoothly flow current to the LED module side using the main line 110 having both ends connected to the anode of the parallel LED line 2A2 of the power supply C and the common cathode LED module 2A. In addition, the independent driving unit 10 can smoothly perform the control of the minimum lighting current in the microampere unit by using the constant current control method as described above.

In addition, referring to FIG. 3 , a circuit capable of inspecting the common anode LED module 2B may be configured as follows. One independent driving unit 10 is disposed between the parallel LED line 2B2 and the ground D of any one of the common anode LED modules 2B. The independent driving unit 10 may be arranged as many as the number of parallel LED lines 2B2 as described above. In the drawing, a common anode LED module 2B having three parallel LED lines 2B2 is shown, and accordingly, an inspection circuit in which three corresponding independent driving units 10 are disposed is shown, but the number can be any number as needed. can be increased. Different independent driving units 10 are connected in parallel to independently drive the corresponding parallel LED lines 2B2, respectively, and are indicated by different channels (eg, CH1, CH2, CH3). Independent driving unit 10, as described above, the power supply C and ground ( It has a power structure insulated from D), and thus the insulated power ground 151 , 152 , and 153 having a reference potential different from that of the ground D of the test circuit can be formed. However, in the circuit configuration as shown in FIG. 3, if necessary, the reference potential of the insulated power ground (151, 152, 153) may coincide with the ground (D) of the entire inspection circuit, for example, the connection line 160 It is also possible to unify the reference potential using the In addition, the inspection circuit may receive a control signal from an operation unit (E) capable of operation such as setting a control signal, and an external control unit (F) connected to the operation unit (E), and an external communication line for transmitting the control signal Insulation from each independent driving unit 10 is as described above.

With such a circuit configuration, a lighting current can flow through each parallel LED line 2B2 of the common anode LED module 2B by using the main line 110 of the independent driving unit 10 connected in parallel with each other. Each independent driving unit 10 receives the operating power of the internal circuit from the insulated power supply unit 131 insulated from the outside, and the control signal is also applied through the insulated communication unit 132 insulated from the external communication line. The remaining parts other than the line 110 may be viewed in an insulated state. Therefore, it is possible to smoothly flow current to the LED module side by using the main line 110 having both ends connected to the power supply C and the anode of the parallel LED line 2B2 of the common anode LED module 2B. In addition, the independent driving unit 10 can smoothly perform the control of the minimum lighting current in the microampere unit by using the constant current control method as described above.

However, as described above, in the case of the inspection circuit of the common anode LED module 2B as shown in FIG. 3, if necessary, the reference potential of each independent driving unit 10 may be matched with the ground D of the entire circuit. Such an example is shown in FIG. 3 . For example, the test circuit may be configured by adding a connection line 160 that matches the reference potential by connecting the insulated power supply unit (refer to 131 in FIG. 1 ) of the independent driving unit 10 and the ground D. However, it is not necessary to do so, and the connection line 160 may be removed. The connection line 160 is substantially connected between the insulated power source 131 and the ground D to match the reference potential, and the insulated power ground 151 , 152 , 153 is the reference potential of the insulated power source 131 . In the drawing, the connection line 160 is indicated as a line connected to the insulated power ground (151, 152, 153) for convenience. This notation is for revealing the characteristics of the connection line 160 on the entire circuit, and may be different from the general circuit symbol like the above-described insulated power ground 150 .

In this form, each independent driving unit 10 including an insulating structure is configured as a kind of parallel circuit and can be suitably applied to the common cathode LED module 2A or the common anode LED module 2B. That is, the independent driving unit 10 is arranged in parallel between each of the plurality of parallel LED lines 2A2 of the power source C and the common cathode LED module 2A as shown in FIG. 2 , such as the first parallel To form a driving circuit, or as shown in FIG. 3, a plurality of them are arranged in parallel between each of the plurality of parallel LED lines 2B2 of the common anode LED module 2B and the ground D, for example, a second parallel driving circuit can be formed In this case, as described above, the second parallel driving circuit may be formed to include the connection line 160 that connects the insulated power supply unit 131 and the ground D to match the reference potential.

4 is a view illustrating the use state of the integrated LED module inspection device according to an embodiment of the present invention including the independent driving unit and the voltage measuring unit of FIG. 1 .

As described above, the independent driving unit 10 can be applied to either the common cathode LED module 2A or the common anode LED module 2B to drive each LED module. In addition, each LED module can be smoothly operated by configuring the inspection circuit as described above. The integrated LED module inspection device 1 may be configured to include such an independent driving unit 10 and a voltage measuring unit 20 together as shown in FIG. 4 , and hereinafter, for the voltage measuring unit 20 It will be described in more detail.

4 is a diagram exemplarily showing a circuit configuration for one parallel LED line 2A2, 2B2 of the common cathode LED module 2A or the common anode LED module 2B is shown. The voltage measuring unit 20 has the independent driving unit 10 connected to the common cathode LED module 2A as shown in FIG. 4(a), or to the common anode LED module 2B as shown in FIG. When the arrangement is changed by being connected, the connection circuit may be formed to be changed. That is, according to the arrangement of the independent driving unit 10, the voltage measurement unit 20 is one of the parallel LED lines 2A2 of the common cathode LED module 2A, or the common anode LED module 2B of any one It can be selectively connected to the parallel LED line (2B2) to measure the voltage. To this end, the voltage measuring unit 20 is switched according to the connection position of the main line 110 of the independent driving unit 10, and the voltage measuring unit 20 is connected to the parallel LED of any one of the common cathode LED modules 2A. Between the anode of the line 2A2 and the ground D (Fig. 4(a)), or between the power source C and the cathode of the parallel LED line 2B2 of any one of the common anode LED modules 2B (Fig. 4). (b)] may include a switching circuit 23 connected in parallel. The voltage measuring unit 20 is connected in parallel to the switching circuit 23 and the parallel LED lines 2A2 and 2B2 through the switching circuit 23 to measure a voltage (eg, a voltmeter, an amplifier circuit, etc.) ) and the like.

In particular, the switching circuit 23 includes a first connection line 21 connected in parallel to the parallel LED line 2A2 of the common cathode LED module 2A as shown in FIG. As shown in (b), a transfer operation is possible between the second connection lines 22 connected in parallel to the parallel LED lines 2B2 of the common anode LED module 2B, and through this, the voltages of different LED modules can be conveniently measured. The transfer circuit 23 may be formed including, for example, a switching mechanism capable of switching between the first connection line 21 and the second connection line 22 , and as shown through this, an independent driving unit Even if the arrangement of (10) is changed to the common cathode LED module (2A) side or the common anode LED module (2B) side, it is possible to conveniently measure the voltage by simply changing the circuit. That is, the independent driving unit 10 that can freely drive the common cathode LED module 2A and the common anode LED module 2B by changing the arrangement as described above, and the independent driving unit 10 even if the arrangement of the independent driving unit 10 is changed, it is simply a circuit An integrated LED module including a voltage measuring unit 20 that can conveniently measure the voltage of each parallel LED line 2A2, 2B2 of the common cathode LED module 2A or the common anode LED module 2B by switching By configuring the inspection device (1), it is possible to inspect the LED modules of different structures very conveniently and easily.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can realize that the present invention can be embodied in other specific forms without changing the technical spirit or essential features. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

1: Integrated LED module inspection device 2A: Common cathode LED module
2A1: Common cathode node 2A2, 2B2: Parallel LED line
2B: Common Anode LED Module 2B1: Common Anode Node
10: independent drive unit 20: voltage measurement unit
21: first connection line 22: second connection line
23: transfer circuit 110: main line
120: constant current control unit 130: insulation operation unit
121: constant current control circuit 121a: bipolar transistor
122: current detection circuit 123: central control module
124: DA signal converter 125: AD signal converter
131: insulated power supply 131a, 132a: secondary side circuit
132: insulated communication unit 132b: signal processing circuit
141: first insulating converter 141a, 142a: primary side circuit
142: second insulating converter 150, 151, 152, 153: insulated power ground
160: connection line a: LED element
C: Power C': External Power
D: Ground E: Control panel
F: External control unit G, H: Previous inspection device

Claims (9)

connected between power and ground,
A common cathode LED module having a common cathode node and including a plurality of parallel LED lines branched from the common cathode node and having the common cathode node connected to the ground; and
In the integrated LED module inspection apparatus for inspecting all of the common anode LED modules having a common anode node and including a plurality of parallel LED lines branched from the common anode node, and the common anode node is connected to the power source,
The integrated LED module inspection device can be used by changing the location, so that the power source and the common cathode LED module in any one parallel LED line, or between the common anode LED module in any one parallel LED line and the ground and at least one independent driving unit for independently driving the LEDs of each parallel LED line,
The independent drive unit,
Both ends are made of connection terminals that can be selectively connected, and depending on the arrangement of the independent driving unit, both ends are respectively connected to the anode of the parallel LED line of any one of the power source and the common cathode LED module, or both ends are each connected to the common a cathode of any one parallel LED line of the anode LED module, and a main line connected to the ground to energize both ends;
a constant current control unit including a constant current control circuit disposed on the main line to control the current of the main line;
an insulated power supply unit that provides operating power applied to the constant current control unit but is insulated so as not to share a reference potential with the ground; and
It receives an external control signal and applies it to the constant current control unit, including an insulated communication unit electrically insulated from the outside,
The insulated power supply unit is formed to include a primary circuit connected to an external power supply, and a secondary circuit of a first insulated converter in which the secondary circuit is electrically insulated,
The insulated communication unit is formed to include a primary-side circuit connected to an external communication line, and a secondary-side circuit of a second insulated converter in which the secondary-side circuit is electrically insulated,
The constant current control unit may include a current detection circuit disposed at a rear end of the constant current control circuit on the main line, and a current measurement value of the current detection circuit between the current detection circuit and the constant current control circuit, and the current measurement value Further comprising a central control module for feedback control of the constant current control circuit according to,
The constant current control circuit includes a bipolar transistor having a base terminal connected to the central control module side and an emitter and collector terminal connected to the main line, and the constant current control unit is configured to be disposed between the central control module and the base terminal. An integrated LED module inspection device further comprising a digital to analog (DA) signal converter disposed, and an analog to digital (AD) signal converter disposed between the current detection circuit and the central control module. According to claim 1,
At least one voltage measuring unit that is selectively connected to any one of the parallel LED lines of the common cathode LED modules or the parallel LED line of any one of the common cathode LED modules according to the arrangement of the independent driving unit to measure the voltage An integrated LED module inspection device further comprising a. 3. The method of claim 2,
The voltage measuring unit,
It is switched according to the connection position of the main line, and the voltage measuring unit is connected between the anode of the parallel LED line of any one of the common cathode LED modules and the ground, or
An integrated LED module inspection device including a switching circuit for connecting in parallel between the power source and the cathode of any one of the parallel LED lines of the common anode LED module. delete delete delete delete delete delete

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