KR20190018832A - An Apparatus of a Vessel Bridge for Monitoring and Controlling an Navigation LED Light - Google Patents

Abstract

The present invention relates to a device for monitoring and controlling an LED navigation bridge light for a ship, and specifically, to a device for monitoring and controlling an LED navigation bridge light for a ship which enables the monitoring and control of an operation state of an LED navigation light installed in a ship. The device for monitoring and controlling the LED navigation bridge light for a ship comprises: a current conversion module (CV) for converting a current consumed from each LED element disposed in an LED module (L); a detection module (CM) for detecting each detected current in the current conversion module (CV); and a monitoring module (M) for monitoring each of the detected currents transmitted through the detection module (CM). The current conversion module (CV) detects an output of each LED element by different channels.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bridge control system for a ship,

The present invention relates to an LED navigation light bridge control apparatus and, more particularly, to a ship LED navigation light bridge control and monitoring apparatus that enables monitoring and control of an operation state of an LED navigation light installed on a ship.

Incandescent lamps, halogen lamps, or similar lights used in ships, traffic lights, search lights, or floodlights are gradually being replaced by LEDs with the development of LED lighting technology, and technologies for ship application are being developed. The ship's navigational light shall be made in accordance with the provisions of the International Convention for the Prevention of Marine Collisions (COLREG) and the International Maritime Organization (IMO) and shall be made within the limits set forth in such regulations in LED navigation lights. At the same time, when the navigation light is made of LED, it is necessary to develop a control and operation monitoring method according to LED characteristics.

Japanese Patent Application Laid-Open No. 10-2015-0004964 discloses an LED navigation light device and a method of operating the LED navigation light to check the lifetime and the voltage state of the LED navigation light. Also, Patent Registration No. 10-1016777 discloses a luminaire for a battery-direct type LED ship operation.

When the light used for the ship is replaced with LED, it is advantageous for controlling energy efficiency, durability, design convenience, vibration resistance, impact resistance and optical characteristics. However, if multiple LEDs are arranged in chip form, It is difficult. For example, in the case of the LED module, there is an A / D converter installed therein, so that it is difficult to check whether the LED module is abnormal because an error occurs in the LED module and the circuit is not opened. Therefore, in the case of the LED module illumination, it is necessary to provide means for checking the operation state of each LED element or LED chip. The prior art does not disclose such a technique.

The present invention has been made to solve the problems of the prior art and has the following purpose.

Prior Art 1: Patent Publication No. 10-2015-0004964 (Daeyang Electric Ind. Co., Ltd., published on Jan. 14, 2015) LED navigation light device and its operating method Prior Art 2: Patent Registration No. 10-1016777 (published by Kim Young, Inc. on Feb. 25, 2011) Battery direct lighting type LED working light fixture

SUMMARY OF THE INVENTION It is an object of the present invention to provide a marine LED navigation bridge monitoring and control device capable of monitoring the operating state of each LED element of an LED chip applied to a navigation light of a ship.

According to a preferred embodiment of the present invention, the ship LED navigation light bridge control apparatus comprises a current conversion module for converting a current consumed by each LED element disposed in the LED module L; A detection module for detecting each detection current in the current conversion module (CV); And a monitoring module for monitoring each detection current transmitted through the detection module, wherein the current conversion module detects the output of each LED element by a different channel.

According to another preferred embodiment of the present invention, there is further provided a switch unit for selecting an input and an output to each LED element, and an alarm unit having an alarm generating condition for each LED element in accordance with an output current identified in the monitoring module do.

According to another preferred embodiment of the present invention, there is provided at least one connector in which an input channel and an output channel for each LED element are formed.

The control device according to the present invention can individually check the operation state of the LED navigation light installed on the ship. The control device according to the present invention is applied to the operation of an LED navigation light installed on various ships to enable low power consumption monitoring. This makes it possible to automatically detect operational errors that can occur in the navigation of the ship.

FIG. 1 shows an embodiment of a ship LED navigation light bridge control system according to the present invention.
2 shows an embodiment of the monitoring and control apparatus according to the present invention.
FIG. 3 shows an embodiment in which the monitoring control device according to the present invention is formed in a module form.
FIG. 4 illustrates an embodiment in which the monitoring and controlling apparatus according to the present invention is operated.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so that they will not be described repeatedly unless necessary for an understanding of the invention, and the known components will be briefly described or omitted. However, It should not be understood as being excluded from the embodiment of Fig.

FIG. 1 shows an embodiment of a ship LED navigation light bridge control apparatus according to the present invention.

Referring to FIG. 1, the ship LED navigation bridge control apparatus includes a current conversion module CV for converting a current consumed by each LED element disposed in the LED module L; A detection module (CM) for detecting each detection current in the current conversion module (CV); And a monitoring module (M) monitoring each detection current transmitted through the detection module (CM), and the current conversion module (CV) detects the output of each LED element by a different channel.

The bridge monitoring control device can be applied to various lights applied to a ship including a navigation light, and the illumination includes at least one LED chip, and each LED chip can include at least one LED device. The monitoring control device may have a function of detecting or monitoring the output of each navigation light while controlling the operation of a plurality of navigation lights, and may control or monitor the operation of, for example, nine navigation lights. The surveillance control device can continuously control or monitor the operation of the navigation light, and can generate an alarm when an operational error of the navigation light occurs during the operation.

The LED module (L) may include a plurality of LED chips, and each LED chip may be a navigation light. The output of each LED chip can be detected by a current transform module (CV), such as a current transformer. The current conversion module (CV) may be arranged in a structure that does not affect the output of the LED chip, or in a form that minimizes the influence thereof. For example, the current conversion module CV may have a structure that generates an induced current due to a magnetic field change according to a current flowing through each LED chip. The current conversion module CV may convert the output of each LED chip or may detect the output of each LED device formed in each LED chip. However, since the LED chip is provided in the form of a package, the current conversion module (CV) may have a structure for detecting the output of the LED chip and converting it into a current.

The current value according to the output of each LED chip can be transmitted to the detection module CM by the current conversion module CV and the detection module CM classifies each current value and transmits it to the monitoring module M . A current conversion module CV may be disposed for each LED chip, and each current conversion value may be transmitted to the detection module CM through a different channel. The detection module CM may transmit the current value according to the output of each LED chip to the monitoring module M in an appropriate manner. The monitoring module M may compare the conversion current value for each LED chip transmitted from the detection module CM with a predetermined reference value.

Alternatively, a comparator is installed in the detection module CM, and the current value of each LED element transmitted from the current conversion module CV by the comparator can be compared with the reference value. The detection module CM may store reference data for the current value for each LED element, and the reference data may have different values depending on each channel. Thereafter, the comparison result in the comparator can be transmitted to the monitoring module (M), and an alarm can be generated in the alarm generating module (A) according to the comparison result.

The alarm generating module A can notify the occurrence of an error through light emitting means, voice means or other appropriate means, and can be displayed on a display means such as a control monitor installed in the bridge. Further, the alarm generation module (A) can transmit information on the error of the LED navigation light to the portable electronic device of the manager. The alarm generating module (A) may include various types of alarm generating means and is not limited to the embodiments shown.

2 shows an embodiment of the monitoring and control apparatus according to the present invention.

Referring to FIG. 2, the bridge monitoring control device includes a switch unit 22 for selecting input and output for each LED element, and an alarm generating condition for each LED element according to the detected current detected by the monitoring module M. [ And an alarm unit 29 having an alarm signal.

The bridge monitoring and control system is composed of a module independent of the navigation control unit and can be connected to the navigation control unit by appropriate means so as to enable data communication. Or the bridge monitoring control device may form part of the navigation control device.

The bridge monitoring control device may include a control unit 21 for controlling the entire operation and the operation of the switch unit 22 for selecting an LED chip to be detected by the control unit 21 may be controlled. For example, an input to each of nine LED navigation lights 241 to 24n may be selected by the switch unit 22. [ The bridge monitoring control device can operate continuously, and the input to each of the LED navigation lights 241 to 24n can be periodically performed. Each LED navigation light 241 to 24n may have an output of 5 to 10 W while operating at, for example, 200 to 300 VAC, but is not limited thereto. When the LED chips or the navigation lights 241 to 24n measured by the switch unit 22 are determined, the channel can be selected by the channel selection unit 23. However, since the channel is independently set for each of the LED navigational lights 241 to 24n, the channel selection unit 23 means that the channel is opened and becomes detectable by the selection of the switch unit 22. [

The LED module 24 may include a plurality of LED chips or voyage lights 241 to 24n and may include LED indicators 241 to 24n for forming respective LED navigation lights 241 to 24n or respective LED navigation lights 241 to 24n, Can be controlled by the operation controller (Con). The operating state by the operation controller Con can be transmitted to the control unit 21 and the monitor unit 28. [

When a channel for the LED navigation lights 241 to 24n to be detected is selected, the input values are converted into digital values by the digital input unit 25 with respect to each of the LED navigation lights 241 to 24n, The current induced by the input can be detected by the current sensor 26. [ The detected current may be transmitted to the digital output unit 27 and converted to a digital value. The digital input unit 25 can transmit the input information for the predetermined time to each of the LED navigation lights 241 to 24n to the current conversion unit 26. [ The current conversion unit 26 can detect the converted current according to the input of the predetermined time for each of the LED navigation lights 241 to 24n and transmit it to the digital output unit 27. [ The digital output unit 27 can convert the change current for each of the LED navigation lights 241 to 24n into a digital value together with information on the detection time and transmit it to the comparator 27a. The comparator 27a compares the previously stored reference value and the digital conversion value with respect to each of the LED navigation lights 241 to 24n and transmits the contrast result to the monitor unit 28. [

A test current in the form of a pulse can be input to each of the LED navigation lights 241 to 24n for detecting the operating state of each of the LED navigation lights 241 to 24n or for example a short circuit state. In this case, the current generator must be prepared independently. Also, there is a problem that a short-circuit state or similar error of each LED navigation light 241 to 24n must be detected at a predetermined time.

According to one embodiment of the present invention, the operating states of the respective LED navigation lights 241 to 24n can be confirmed in the operating states of the respective LED navigation lights 241 to 24n, and the respective LED navigation lights 241 to 24n are connected to the input terminals of the respective LED navigation lights 241 to 24n. And outputs to the respective LED navigation lights 241 to 24n may be connected to output terminals for the respective LED navigation lights 241 to 24n. A current conversion unit 26 may be arranged between the input and the output and the detected conversion current in the channel forming each input and output may be transmitted to the monitor unit 28. [ The detection period of each of the LED navigation lights 241 to 24n may be set by the switch unit 22 or may be determined by the time at which the detection result is transmitted from the current conversion unit 26. [ In such a detection structure, the operating states of the respective LED navigation lights 241 to 24n can be continuously monitored during the operation.

The monitor unit 28 compares the information transmitted from the operation controller Con or the predetermined reference value with the value transmitted from the digital output unit 27 to determine the operation state of each of the navigation lights 241 to 24n have. The comparison result can be transmitted to the control unit 21 and can be transmitted to the alarm unit 29 when it is determined that an operation error such as a short-circuited state has occurred in one of the navigation lights 241 to 24n as the comparison result. Accordingly, the alarm unit 29 can generate an alarm through the various alarm means described above.

The marine bridge monitoring control system for marine LED navigation lights according to the present invention can be operated in various ways and is not limited to the embodiments shown.

FIG. 3 shows an embodiment in which the monitoring control device according to the present invention is formed in a module form.

Referring to FIG. 3, the supervisory control apparatus NLCM may be formed on a control frame 30 of a printed circuit board or a similar electronic module structure, and may include a plurality of connectors CN1 to CN8. The control frame 30 may be a rectangular substrate as a whole, and the switch module SW and the switch selection unit SL may be disposed at appropriate positions. Each of the connectors CN1 to CN8 may include a plurality of input or output pins, and the switch module SW may also be provided with a plurality of pins.

Each of the connectors CN1 to CN8 may be disposed in the connector block CB and an input pin or an output pin provided in the connector CN1 to CN8 may be connected to each navigation light, a power source, a digital input, or a digital output . For example, one to three connectors (CN1 to CN3) each include six pins, and eighteen pins can be connected to the inputs and outputs of nine LED navigation lights. When the one to three connectors CN1 to CN3 are connected to the LED navigation light, the input pin and the output pin form one channel, and a current conversion unit may be disposed on the pair of input pin and output pin. For example, when eighteen input and output pins are formed in nine navigation lights, nine current conversion units can be arranged for each navigation light. 1 digital input pin, 1 digital output pin, 2 digital input pins, and 2 digital input pins, as well as 4 pins (CN4), 5 connectors (CN5), 6 connectors (CN6) Output pins. For example, one or two digital input pins can be configured to allow digital input for each navigation light.

The switch module SW may include 16 pins such as pins 0 to 9 and pins A to F, and an alarm generating condition may be set. For example, the switch module SW can be set to generate an alarm when 0 mA, 3 mA, 6 mA, ...., 45 mA for the 0 to F pins, respectively. If an alarm generating condition is set for each pin arranged in the switch module SW as described above, it can be selected by the switch selecting unit SL. In operation, an output according to the input by the current conversion unit can be detected by the current conversion unit, and an alarm can be generated if a value smaller than the set value at each pin of the switch module SW is detected.

The surveillance control device (NLCM) can be connected to the main device for navigation light operation and can have an operation switch separately. Also, the input pins and the output pins disposed in the connectors 5 to 8 (CN5 to CN8) may be dry contact pins that are not voltage-applied. Accordingly, power consumption due to the installation of the monitoring control apparatus (NLCM) is reduced, and interference may not occur during the operation of the navigation light.

The supervisory control device (NLCM) can be made in various structures and is not limited to the embodiments shown.

FIG. 4 illustrates an embodiment in which the monitoring and controlling apparatus according to the present invention is operated.

4, the supervisory control device can be made of a substrate structure, and a microprocessor, a resistor, a capacitor or the like electronic component can be disposed in the operation frame 30. The operation frame 30 can be made into a standalone module structure, connected to a main device for operation of a navigation light, and can be powered from the main device. A digital input pin module 44 in which a plurality of input pins are disposed can be disposed on one side of the operation frame 30 and an output pin having an output pin corresponding to the number of input pins is disposed, 45 may be disposed on the other side of the operation frame 30. [ Each digital input pin and its corresponding output pin can form one channel. And each input pin and output pin can be connected by respective current conversion units. As described above, each input pin and output pin can be a dry contact input and a dry contact output.

A power status indicator 42 indicating whether power is supplied from the main device to the operation frame 30 and an operation status indicator 43 indicating the operation status of the monitoring and control device may be disposed. The actuation frame 30 can be made in a variety of configurations and various display means for indication of the power supply state or operating state can be placed in the actuation frame 30 and is not limited to the embodiment shown.

The control device according to the present invention can individually check the operation state of the LED navigation light installed on the ship. The control device according to the present invention is applied to the operation of an LED navigation light installed on various ships to enable monitoring with low power consumption. This makes it possible to automatically detect operational errors that can occur in the navigation of the ship.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

21: control unit 22: switch unit
23: Channel selection unit 24: LED module
25: digital input unit 26: current conversion unit
27: Digital output unit 27a: Comparator
28: Monitor unit 29: Alarm unit
30: Control frame 42: Power status indicator
43: Operation status indicator 44: Digital input pin module
45: Digital output pin module 241 to 24n: LED navigation light
A: Alarm generating module CB: Connector block
CM: Detection module CN1 to CN8: Connector
Con: Operation controller CV: Current conversion module
L: LED module M: Monitoring module
NLCM: Surveillance control unit SL: Switch selection unit
SW: Switch module

Claims (3)

A current conversion module (CV) for converting a current consumed from each LED element disposed in the LED module (L);
A detection module (CM) for detecting each detection current in the current conversion module (CV); And
And a monitoring module (M) for monitoring each detection current transmitted through the detection module (CM)
Wherein the current conversion module (CV) detects the output of each LED element by different channels. The monitoring module according to claim 1, further comprising: a switch unit (22) for selecting an input and an output for each LED element; and an alarm unit (29) having an alarm generating condition for each LED element ) For the marine vessel. The marine vessel navigation bridge control device according to claim 1, comprising at least one connector (CN1 to CN3) having input and output channels for each LED element.

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