KR102207418B1 - Light emitting diode apparatus fault diagnosis rpoviding easy maintenance - Google Patents

Abstract

An LED lighting apparatus according to the embodiments of the present invention includes: a housing having a first connector and a second connector; a converter unit provided in the housing to convert AC power supplied from the outside into DC power; a first detection unit provided in the housing to output a first detection power, according to detection of the AC power inputted to the converter unit, through the first connector; a second detection unit provided in the housing to output a second detection power, according to detection of the DC power outputted from the converter unit, through the second connector; an LED module provided in the housing to output light when the DC power is supplied from the converter unit; and a fault diagnosis unit disposed outside the housing and connected to and disconnected from the first connector and the second connector to diagnose at least one of whether external power is supplied, whether the converter unit is faulty, and whether the LED module is faulty, according to at least one of the first detection power supply and the second detection power supply. Accordingly, normal operation is checked without disassembly or circuit damage.

Description

LED luminaire device including fault diagnosis unit for easy maintenance {LIGHT EMITTING DIODE APPARATUS FAULT DIAGNOSIS RPOVIDING EASY MAINTENANCE}

The present invention relates to an LED luminaire device including a trouble diagnosis unit that is easy to maintain.

If it is necessary to diagnose a failure of a general LED luminaire, disconnect the power input line of the LED luminaire and the DC power line connected to the LED module, or remove the sheath and connect the measurement device to check the failure, or visually check the operation status of the LED module. The fault diagnosis was judged as a method of checking.

Accordingly, there has been a tendency that the workload and working time of the person in charge of performance inspection, maintenance, or repair tend to be excessively increased, and damage to the LED luminaire, such as disconnection or covering of a conductor, may occur.

Patent Publication 10-2011-0092100 (Publication date August 17, 2011)

The LED luminaire device according to an embodiment of the present invention is for a person in charge to check whether the LED luminaire device operates normally without disassembling the LED luminaire device or damage to the circuit.

The subject of the present application is not limited to the subject mentioned above, and another subject not mentioned will be clearly understood by those skilled in the art from the following description.

According to one aspect of the present invention, a housing provided with a first connector and a second connector; A converter unit provided in the housing and converting AC power supplied from the outside into DC power; A first detection unit provided in the housing and configured to output a first detection power through the first connector according to detection of the AC power input to the converter unit; A second detection unit provided in the housing and configured to output a second detection power through the second connector according to the detection of the DC power output from the converter unit; An LED module provided in the housing and outputting light when DC power is supplied from the converter unit; And whether or not external power is supplied according to at least one of the first detection power and the second detection power, and failure of the converter unit, which is disposed outside the housing to connect and disconnect with the first connector and the second connector. There is provided an LED luminaire device comprising a fault diagnosis unit configured to diagnose at least one of whether or not the LED module is faulty.

The first detection unit magnetically connects and electrically insulates the input terminal of the converter unit and the failure diagnosis unit, and the second detection unit branches current to the failure diagnosis unit when the failure diagnosis unit is connected, and disconnects the failure diagnosis unit. It can prevent short circuit or electric shock to workers.

The fault diagnosis unit comprises a first sensing unit for sensing the voltage of the first detection power without sensing the current of the first detection power input from the first connector, and of the second detection power input from the second connector. A second sensing unit that senses current and voltage, derives whether the AC power input to the converter unit is normal according to the voltage sensing signal of the first sensing unit, and according to the voltage sensing signal and the current sensing signal of the second sensing unit. It may include a control unit for deriving whether the DC power output from the converter unit is normal.

The second sensing unit includes a variable load circuit unit connectable to the second connector, and the variable load circuit unit initially sets a maximum measurement resistance by switching according to the control of the control unit, and is supplied through the second connector. 2 When detection power is applied to the set maximum measurement resistance, the controller may derive whether the voltage of the maximum measurement resistance is within a sensing range.

When the voltage of the maximum measurement resistance is out of the sensing range, the variable load circuit unit switches according to the control of the control unit to set a measurement resistance smaller than the maximum measurement resistance, and the second voltage supplied through the second connector When detection power is applied to the set measurement resistance, the controller may derive whether the voltage of the measurement resistance is within a sensing range.

The LED luminaire device according to an embodiment of the present invention has a fault diagnosis unit that can be disposed outside the housing, so that a person in charge can check whether the LED luminaire device operates normally without disassembling the LED luminaire device or damage to the circuit.

The effects of the present application are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 shows an LED luminaire device according to an embodiment of the present invention.
2 shows an example of a circuit of the first detection unit.
3 shows an example of a circuit of the second detection unit.
4 shows a block diagram of a fault diagnosis unit.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the accompanying drawings are only described in order to more easily disclose the contents of the present invention, and the scope of the present invention is not limited to the scope of the accompanying drawings. You will know.

In addition, terms used in the present application are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance.

1 shows an LED luminaire device according to an embodiment of the present invention. As shown in FIG. 1, the housing 110, the converter unit 120, the first detection unit 130, the second detection unit 140, the LED module 150, and the fault diagnosis unit according to an embodiment of the present invention. Including 160.

The housing 110 is provided with a first connector 111 and a second connector 113.

The converter unit 120 is provided in the housing 110 and converts AC power supplied from the outside into DC power. The AC power supplied from the outside may be an AC power supply of 60Hz 22OV in Korea, but is not limited thereto.

The first detection unit 130 is provided in the housing 110 and is configured to output first detection power according to detection of the AC power input to the converter unit 120 through the first connector 111. The first detection unit 130 may form the first detection power by lowering the voltage level of the AC power to an appropriate level. The appropriate voltage level of the first detection power source may be set differently according to the design of the present invention.

The second detection unit 140 is provided in the housing 110 and is configured to output a second detection power through the second connector 113 according to detection of the DC power output from the converter unit 120. Since the LED (Light Emitting Diode) module is driven by DC power, the converter unit 120 converts AC power into DC power.

Since the output of the LED module 150 is varied, the voltage level of the DC power source required by the LED module 150 may also vary. Accordingly, the voltage level and current level of the DC power supplied by the converter unit 120 may be at least one.

The LED module 150 is provided in the housing 110 and outputs light when DC power is supplied from the converter unit 120.

The fault diagnosis unit 160 is disposed outside the housing 110 and can be connected to and disconnected from the first connector 111 and the second connector 113, according to at least one of the first detection power supply and the second detection power supply. It is configured to diagnose whether at least one of whether an external power is supplied, whether the converter unit 120 has failed, and whether the LED module 150 has failed.

In the LED luminaire device according to an embodiment of the present invention, the fault diagnosis unit 160 is disposed outside the housing 110 to diagnose a failure of the LED luminaire device. Unlike the LED luminaire device according to the embodiment of the present invention, when the fault diagnosis unit 160 is inside the housing 110, the failure diagnosis unit 160 must be provided for each LED luminaire device, so that the production cost may increase.

When the failure diagnosis unit 160 is inside the housing 110, the failure diagnosis unit 160 must be replaced by disassembling the housing 110 for each LED luminaire for which the operation of the failure diagnosis unit 160 is not normally performed. Maintenance/repair can be difficult.

In addition, in the absence of the first connector 111 and the second connector 113 of the present invention, even if the fault diagnosis unit 160 is disposed outside the housing 110, the operator removes the covering of the input terminal and the output terminal of the converter. Since the fault diagnosis unit 160 needs to be connected after performing the operation, the ease of maintenance/repair may be very poor.

In the case of the present invention, the first connector 111 and the second connector 113 are provided in the housing 110 so that they are exposed to the outside, and the first connector whenever a fault diagnosis unit 160 outside the housing 110 is required. It is connected to 111 and the second connector 113 so that it is possible to easily check whether or not the LED luminaire has a failure. Accordingly, one failure diagnosis unit 160 can diagnose the failure of the converter unit 120 and the LED module 150 provided in each of the plurality of housings 110.

In this way, since the first connector 111 and the second connector 113 may be exposed to the external environment of the housing 110, the first connector 111 is used to prevent a short or electric shock to a worker due to dust or moisture. And a waterproof cap covering the second connector 113 may be provided.

After removing the waterproof cap, the operator can perform the failure diagnosis by connecting the failure diagnosis unit 160 to the first connector 111 and the second connector 113. After the failure diagnosis is completed, the operator separates the failure diagnosis unit 160 from the first connector 111 and the second connector 113 and covers the first connector 111 and the second connector 113 with a waterproof cap. I can.

The first connector 111 and the second connector 113 described above may be a magnet type connector or an insertion type connector, but are not limited thereto. The magnet type connector may be coupled with the connector of the fault diagnosis unit 160 by magnetic force.

The insertion type connector may have a structure in which an insertion groove is formed in one of the connector of the fault diagnosis unit 160 and the first connector 111 and a protrusion is formed in the other. Similarly, an insertion groove may be formed in one of the connector and the second connector 113 of the fault diagnosis unit 160 and a protrusion may be formed in the other.

The magnet type connector can be less affected by the external environment than the plug-in type connector. That is, when dust or moisture outside the housing 110 enters the insertion groove, a fault diagnosis may not be accurately performed.

Meanwhile, as described above, since the first connector 111 and the second connector 113 may be exposed to the outside of the housing 110, a short circuit may occur due to moisture or dust. In addition, the voltage level of the AC power may be 220V, and the voltage level and current level of the DC power output from the converter unit 120 may also be up to 280V and 10A, so that an operator may be electrocuted.

To prevent this, the first detection unit 130 may magnetically connect and electrically insulate the input terminal of the converter unit 120 and the fault diagnosis unit 160. In addition, the second detection unit 140 diverges the current to the fault diagnosis unit 160 when the faulty end 160 is connected, and when the fault diagnosis unit 160 is disconnected, dust or moisture through the FET switching element to be described later. It can prevent short circuit or electric shock to the operator.

For example, as shown in FIG. 2, the first detection unit 130 may include a transformer. The primary terminal of the transformer may be connected to the input terminal of the converter unit 120 to which the AC power of FIG. 1 is input, and the secondary terminal of the transformer may be connected to the first connector 111 of FIG. 1.

In addition, as shown in FIG. 3, the second detection unit 140 may include a field effect transistor (FET). The first terminal connected to the drain terminal of the FET of FIG. 3 and the second terminal connected to the gate terminal of the FET may be connected to the output terminal and the terminal of the converter unit 120.

Also, the source terminal of the FET may be connected to the terminal portion. The terminal portion may be connected to the second connector 113. The FET may be switched by applying a gate signal from the control unit 167 of the fault diagnosis unit 160 to the gate terminal of the FET through the terminal unit, which will be described later.

In the case of the FET of the second detection unit 140, since the impedance from the fault diagnosis unit 160 to the second detection unit 140 is large, a short circuit caused by dust or moisture may prevent an electric shock to the operator.

On the other hand, the fault diagnosis unit 160 may operate as a separate DC power supply instead of the AC power and DC power of the converter unit 120. Unlike the present invention, when the fault diagnosis unit 160 operates with an external AC power input to the converter unit 120, the failure diagnosis unit 160 must have a separate power converter, so the structure of the failure diagnosis unit 160 is It can get complicated. As shown in FIG. 4, separate DC power of the fault diagnosis unit 160 may be supplied by the power supply unit 161.

Meanwhile, as shown in FIG. 4, the failure diagnosis unit 160 may include a first sensing unit 163, a second sensing unit 165, and a control unit 167.

The first sensing unit 163 may sense the voltage of the first detection power without sensing the current of the first detection power input from the first connector 111.

The second sensing unit 165 may sense the current and voltage of the second detection power input from the second connector 113.

The control unit 167 derives whether the AC power input to the converter unit 120 is normal according to the voltage sensing signal of the first sensing unit 163, and the voltage sensing signal and the current sensing signal of the second sensing unit 165 According to this, it is possible to derive whether the DC power output from the converter unit 120 is normal.

The voltage input to the first sensing unit 163 of the fault diagnosis unit 160 is greater than 0 volts and less than 1 volt, and the first sensing unit 163 may amplify this and input it to the control unit 167.

As described above, the first sensing unit 163 may sense only the voltage without sensing the current of the first detection power, and the second sensing unit 165 may sense the current and voltage of the second detection power. .

The first detection power may be based on 60Hz 220V AC power supplied by KEPCO, and since it hardly occurs when the KEPCO grid fails to supply current, the first sensing unit 163 of the fault diagnosis unit 160 is Only voltage sensing can be performed without sensing.

In contrast, the LED module 150 is applied with a voltage but does not emit light in some cases. Accordingly, the second sensing unit 165 may check whether electric energy capable of emitting light is supplied by the LED module 150 by sensing the current and voltage of the second detection power.

Meanwhile, the second sensing unit 165 may include a variable load circuit unit 165A connectable to the second connector 113. The variable load circuit unit 165A switches under the control of the control unit 167 to initially set the maximum measurement resistance, and when the second detection power supplied through the second connector 113 is applied to the set maximum measurement resistance, the control unit (167) can derive whether the voltage of the maximum measurement resistance is in the senseable range.

The variable load circuit unit 165A may branch the DC power output from the converter unit 120 to the fault diagnosis unit 160 through the second detection unit 140 so that the converter unit 120 operates as usual. The converter unit 120 outputs a large voltage (15V ~ 280V) and current (0.7A ~ 10A) according to the type of the LED module 150, and the variable load circuit unit 165A uses a switching element accordingly. Thus, the voltage and current of the DC power output from each converter unit 120 can be automatically sensed.

The reason why the variable load circuit unit 165A is initially set as the maximum measurement resistance is that the width of the current output from the converter unit 120 is large, so that an excessive current can be prevented from flowing into the fault diagnosis unit 160. That is, when the initial setting measurement resistance is small and the current output from the converter unit 120 is large (for example, 10A), the current flowing into the failure diagnosis unit 160 becomes larger than necessary and the failure diagnosis unit 160 The circuit of may be damaged.

When the control unit 167 deduces that the voltage of the maximum measurement resistance is in the senseable range, the current can be calculated using the initially set maximum measurement resistance and the measured voltage.

On the other hand, when the voltage of the maximum measurement resistance is out of the sensing range, the variable load circuit unit 165A switches under the control of the controller 167 to set a measurement resistance smaller than the maximum measurement resistance, and connects the second connector 113 When the second detection power supplied through is applied to the set measurement resistance, the control unit 167 may derive whether the voltage of the measurement resistance is within a senseable range.

When the control unit 167 deduces that the voltage of the measurement resistance is in the senseable range, the current can be calculated using the set measurement resistance and the measured voltage. Conversely, if the control unit 167 deduces that the voltage of the measurement resistance is outside the senseable range, a measurement resistance smaller than the measurement resistance is set and the above-described process may be repeated.

Meanwhile, as shown in FIG. 4, the failure diagnosis unit 160 may further include a display unit 169. The display unit 169 may display operation information for a normal operation signal. In addition, the display unit 169 may display information on the abnormal operation signal. The display unit 169 may display operation information including RGB LEDs in various colors. The operation information may include a normal operation state, an abnormal operation state, a state of the input side AC power of the converter unit 120, and a state of the output side DC power of the converter unit 120, but are not limited thereto.

As described above, the embodiments according to the present invention have been looked at, and the fact that the present invention can be embodied in other specific forms without departing from its spirit or scope other than the above-described embodiments is understood by those of ordinary skill in the art. It is self-evident to Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and may be modified within the scope of the appended claims and equivalents thereof.

Housing(110)
First connector (111)
Second connector (113)
Converter unit 120
The first detection unit 130
The second detection unit 140
LED module(150)
Fault diagnosis unit (160)
Power supply unit (161)
First sensing unit 163
Second sensing unit 165
Variable load circuit part (165A)
Control unit 167

Claims (4)

A housing including a first connector and a second connector;
A converter unit provided in the housing and converting AC power supplied from the outside into DC power;
A first detection unit provided in the housing and configured to output a first detection power according to detection of the AC power input to the converter unit through the first connector;
A second detection unit provided in the housing and configured to output a second detection power according to the detection of the DC power output from the converter unit through the second connector;
An LED module provided in the housing and outputting light when DC power is supplied from the converter unit; And
It is disposed outside the housing and can be connected to and disconnected from the first connector and the second connector, and whether external power is supplied according to at least one of the first detection power and the second detection power, and whether the converter unit has a failure And a failure diagnosis unit configured to diagnose at least one of failure of the LED module,
The first detection unit magnetically connects and electrically insulates the input terminal of the converter unit and the fault diagnosis unit,
The second detection unit includes a switching element,
According to the switching operation of the switching element, the fault diagnosis unit and the second detection unit are electrically connected and disconnected,
The switching element, the LED luminaire device, characterized in that branching current to the fault diagnosis unit and preventing a short circuit or electric shock to an operator.
The method of claim 1,
The trouble diagnosis unit
A first sensing unit configured to sense a voltage of the first detection power without sensing a current of the first detection power input from the first connector,
A second sensing unit sensing current and voltage of the second detection power input from the second connector,
Derives whether the AC power input to the converter unit is normal according to the voltage sensing signal of the first sensing unit, and whether the DC power output from the converter unit is normal according to the voltage sensing signal and the current sensing signal of the second sensing unit LED luminaire device comprising a control unit for deriving.
The method of claim 2,
The second sensing unit includes a variable load circuit unit connectable to the second connector,
The variable load circuit unit is switched according to the control of the control unit to initially set a maximum measured resistance,
When the second detection power supplied through the second connector is applied to the set maximum measurement resistance, the control unit derives whether the voltage of the maximum measurement resistance is within a sensing range.
The method of claim 3,
When the voltage of the maximum measurement resistance is out of the sensing range, the variable load circuit unit switches according to the control of the controller to set a measurement resistance smaller than the maximum measurement resistance
When the second detection power supplied through the second connector is applied to the set measurement resistance, the control unit derives whether the voltage of the measurement resistance is within a senseable range.

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