KR20220059140A - Integrated remote lighting control system for ships and offshore facilities - Google Patents

Abstract

The present invention relates to an integrated remote lighting control system of a ship and a marine facility, including: a lighting (10) which is distributed and installed in a plurality of target areas and includes ECGs (11, 13, 15); an MD sensor (20) which is installed to sense motions and illuminance in the target areas; a lighting controller (30) which includes a gateway and an actuator in the same network to divide the lighting (10) into a plurality of groups and connect the same; and a central controller (40) which is connected to the lighting controller (30) through a network and controls the lighting (10) with a set power saving algorithm. Accordingly, automatic and remote lighting control using sensors as well as a general manual operation are performed in the entire area of a ship and marine equipment, thereby improving energy efficiency and the lifespan of a lighting device, and quickly confirming and responding to an emergency situation, thus ultimately reducing maintenance costs and energy.

Description

Integrated remote lighting control system for ships and offshore facilities}

The present invention relates to lighting of ships and offshore facilities, and more specifically, integrated remote lighting control of ships and offshore facilities by grafting hardware and software technology for remote control to various sensor technologies for lighting installed on ships or offshore facilities It's about the system.

In general, since general lighting equipment is manually controlled through an electric distribution board or a switch in ships and offshore facilities, it is difficult to expect to understand the state of the lighting equipment. A lamp indicating the lighting control status is sometimes provided, but the lamp has a short lifespan and lowers energy efficiency. It is difficult to operate the entire external lighting with a manual controller, and it is impossible to control the lighting when the power is cut off.

Patent documents such as the following Korean Patent Application Laid-Open No. 2015-0045185 and Korean Patent Application Laid-Open No. 2017-0004369 are known as prior art documents that can be referenced in this regard.

The former is a human body detection sensor installed in a pre-designated area to detect whether there is a person nearby; and a controller that controls the brightness of the guidance lamp in the corresponding area to a preset maximum when there is a person as a signal of the human body detection sensor, and controls the brightness of the guidance lamp to a preset minimum when there is no person. Accordingly, an effect of saving energy is expected rather than always illuminating at the maximum brightness.

The latter is a lighting control unit for generating a power path control signal to selectively supply power to the power consuming means; a power supply unit for varying an output path of the generated power according to a power path control signal generated from the lighting control unit; And it includes a lighting driver for driving the lighting with the power of the power supply. Accordingly, an effect of efficiently operating power as well as preventing power waste is expected.

However, according to the above-mentioned prior patent, since it is applied to a relatively limited area, it reveals a limitation in terms of overall lighting energy saving.

Korean Patent Application Laid-Open No. 2015-0045185 "A lighting device for a ship and a lighting control method using the same" (Published on: April 28, 2015) Korean Patent Publication No. 2017-0004369 "Lighting control device for offshore structures" (published on: 2017.01.11.)

An object of the present invention to improve the conventional problems as described above is, based on the sensor information of the entire area in ships and offshore facilities, it is possible to automatically adjust the brightness for each zone/time and remotely monitor the control status using a program. It is to provide an integrated remote lighting control system for ships and offshore facilities.

In order to achieve the above object, the present invention provides an integrated remote lighting control system for ships and offshore facilities, comprising: lighting installed in a plurality of target areas distributedly, and having an ECG; MD detector installed to detect motion and illuminance in a plurality of target areas; a lighting controller having a gateway and an actuator in the same network to divide and connect the lighting into a plurality of groups; and a central controller connected to the lighting controller through a network and controlling the lighting with a set power saving algorithm.

As a detailed configuration of the present invention, the lighting controller connects a lighting group with an addressable first CECG to a second gateway, connects a lighting group with a second dimmable ECG to a dimming actuator, and connects the remaining lighting groups to a switch actuator characterized in that

As a detailed configuration of the present invention, the central controller stores and executes a power saving algorithm for switching some lights of the target area between maximum brightness, medium brightness, and light off in response to human movement, change of day and night, and change of season do it with

As a detailed configuration of the present invention, the central controller monitors abnormal conditions in addition to turning on and off lights over a network and displays them on a monitor.

As a detailed configuration of the present invention, it is characterized in that the central controller reflects the changed power saving information through a network-connected local controller to the power saving algorithm.

As described above, according to the present invention, not only general manual operation in the entire area of ships and offshore facilities, but also automatic and remote lighting control using sensors is possible, increasing energy efficiency and lifespan of lighting equipment, and early identification and response to emergency situations This is fast and has the effect of ultimately saving maintenance costs and energy.

1 is a block diagram showing a lighting system according to the present invention;
2 is a schematic diagram showing the lighting arrangement of the system according to the present invention;
3 is a schematic diagram showing a control screen of a system according to the present invention;
4 is a schematic diagram showing a lighting control state according to the present invention

Hereinafter, an embodiment of the present invention will be described in detail based on the accompanying drawings.

The present invention proposes an integrated remote lighting control system for ships and offshore facilities. It is intended for lighting installed in ships or offshore facilities, but is not necessarily limited thereto.

According to the present invention, the lighting 10 having the ECGs 11, 13, and 15 is distributed and installed in a plurality of target areas.

Referring to FIG. 1 , an electronic control gear (ECG) provided in each is shown along with a plurality of lights 10 . The lighting 10 is preferably an LED in terms of power saving, but is not limited thereto. ECG is equipped with a circuit that controls the on and off of the corresponding light in response to an external signal. In ships and offshore facilities, target areas include common rooms, workstations, cargo control rooms, machinery rooms, corridors, and stairs.

In addition, according to the present invention, the MD sensor 20 is installed to detect motion and illuminance in a plurality of target areas.

In Fig. 1, one MD detector 20 is shown, but it is distributedly installed in the target area. The MD sensor 20 is configured to include a part that detects human motion (approach) and a part that detects illuminance (light amount). The MD detector 20 is an important element in the design of saving energy consumed by lighting.

According to the present invention, the lighting controller 30 has a structure including a gateway and an actuator in the same network so that the lighting 10 is divided into a plurality of groups and connected.

In FIG. 1 , the lighting 10 divided into three groups is connected to the lighting controller 30 . The lighting controller 30 includes a first gateway 31, a second gateway 32, a dimming actuator 33, a switch actuator 35, a power supply unit, a universal interface, and the like on an internal network/power cable. .

As a detailed configuration of the present invention, the lighting controller 30 connects the lighting group with the addressable first CECG 11 to the second gateway 32, and connects the lighting group with the second dimmable ECG 13 to the dimming actuator. connected to (33), and characterized in that the remaining lighting group is connected to the switch actuator (35).

The second gateway 32 is an addressable 'DALI gateway' and connects up to 64 lights 10 in series to form one group. The dimming actuator 33 is an actuator that adjusts brightness by varying the operating voltage, and forms another group by connecting a plurality of lights 10 in series. The switch actuator 35 is an actuator that causes on/off with a relay, and forms another group by connecting a plurality of lights 10 in series. The dimming actuator 33 and the switch actuator 35 do not require the same address designation expression as the second gateway 32 , but do not exclude the address designation expression.

In addition, according to the present invention, the central controller 40 for controlling the lighting 10 with a set power saving algorithm is connected to the lighting controller 30 and the network through a network.

In FIG. 1 , a state in which the central controller 40 is connected to the first gateway 31 of the lighting controller 30 through a network is shown. The central controller 40 is disposed in the workstation to notify the lighting control state or emergency situation. The central controller 40 is a microprocessor, a memory, and a microcomputer circuit having an input/output interface. The power saving algorithm is stored and executed in the form of programs and data in the memory of the central controller 40 . Each group of lights 10 is remotely controlled according to a power saving algorithm.

Referring to FIG. 2 , a state in which the lighting 10 of a specific target area is more subdivided into groups of symbols 10A, 10B, 10C, 10D, 10E, and 10F is exemplified. For the lighting of each group, the type of lamp, brightness control pattern, on/off cycle, etc. are applied differentially. And some of them can be changed through the central controller 40 , the local controller 50 , and the like.

Referring to FIG. 3 , the entire target area of ships and offshore facilities is displayed through the monitor 43 of the central controller 40 . The target area on the monitor 43 can be partially enlarged as shown in FIG. 2 by input of a mouse or the like.

As a detailed configuration of the present invention, the central controller 40 performs a power saving algorithm for switching some lights 10 of the target area between maximum brightness, medium brightness, and light off in response to human movement, change of day and night, and change of season. It is characterized by saving and executing.

In FIG. 1 , the central controller 40 is connected to the MD detector 20 , the fire detector 25 , the lighting controller 30 , the wireless terminal 45 and the like through a network. The power saving algorithm of the central controller 40 is stored and executed in the form of a plurality of subroutine programs. This applies more specifically in the following way, but is also extensible.

1) In the case of hallways, common stairs, and common rooms, only 50% brightness is maintained when there is no human movement, and 100% brightness is maintained for 5 minutes (adjustable) when human movement is detected. If it is exceeded, the brightness is lowered to 50% again.

2) In particular, in the case of a common room, for convenience, a local controller 50 is placed at the entrance to form a different group according to the characteristics of each room, the group is stored in the memory, and the lighting is controlled as a group.

3) A separate monitoring system (not shown) is installed in the cargo control room to check the status, lifespan, and energy consumption of lighting in real time.

4) The lighting installed outside allows the lighting to be automatically controlled according to a set time. For example, in summer, turn off the lights from 6 am to 7 pm and turn on the lights from 7 pm to 6 am.

5) In the case of a machine room where large equipment is placed, there is no need to maintain 100% brightness because there is no movement of people except for regular inspection at a fixed time. When there is no human movement, only 50% brightness is maintained, and when a human movement is detected, the brightness is maintained at 100% for a specified area around the area detected by the motion sensor and for 30 minutes (adjustable), after which other motion is detected. If not, lower the brightness to 50% again.

Meanwhile, the wireless terminal 45 is a mobile device that enables wireless control, and communication is possible through the wired/wireless router 41 .

As a detailed configuration of the present invention, the central controller 40 monitors an abnormal state in addition to turning on and off the lighting 10 over the network and displays it on the monitor 43 .

Referring to FIG. 4 , the lighting state of a specific target area is displayed on the monitor 43 of the central controller 40 . The light 10 is expressed in different colors for the power off state (OFF), the normal operating state (ON), the internal component problem (LF) of the light, and the lamp problem (FF) of the light. This can be determined through the central controller 40 connected to all the lights 10 and the network. If it is determined that the unnecessary lighting state of the lighting 10 is maintained, a quick action is possible.

As a detailed configuration of the present invention, the central controller 40 reflects the power saving information changed through the network-connected local controller 50 to the power saving algorithm.

In FIG. 1 , the local controller 50 is connected to the central controller 40 through the lighting controller 30 . The local controller 50 is also a microcomputer circuit like the central controller 40, but is HMI (Human Machine Interface) oriented and is arranged in a specific target area. The input of the local controller 50 is a touch screen, and items related to the power saving algorithm can be changed. For example, if the lighting control of a specific target area does not conform to power saving and is changed to the local controller 50 , this information is reflected in the power saving algorithm of the central controller 40 . However, the input change of the local controller 50 is limitedly set so as not to cause a system abnormality.

The system of the present invention is capable of interface extension with other equipment. The emergency power restoration system automatically turns on only the emergency light by supplying power in a situation in which the power of the ship/offshore facility is cut off through the safety circuit configuration.

If the central controller 40 inputs a signal from the fire detector 25, the lighting 10 of the set evacuation route is unconditionally turned on prior to the power saving algorithm, and emergency power is applied if necessary.

The present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such variations or modifications fall within the scope of the claims of the present invention.

10: Illumination 11, 13, 15: ECG
20: MD detector 25: fire detector
30: lighting controller 31, 32: gateway
33: dimming actuator 35: switch actuator
40: central controller 41: router
43: monitor 45: wireless terminal
50: local controller

Claims (5)

An integrated remote lighting control system for ships and offshore facilities, comprising:
Illumination (10) distributed in a plurality of target areas and provided with ECGs (11, 13, 15);
MD detector 20 installed to detect motion and illuminance in a plurality of target areas;
a lighting controller 30 having a gateway and an actuator in the same network to divide and connect the lighting 10 into a plurality of groups; and
The integrated remote lighting control system for ships and offshore facilities, comprising: a central controller (40) connected to the lighting controller (30) through a network and controlling the lighting (10) with a set power saving algorithm. The method according to claim 1,
The lighting controller 30 connects the lighting group with the addressable first CECG 11 to the second gateway 32, and the lighting group with the second dimmable ECG 13 to the dimming actuator 33, An integrated remote lighting control system for ships and offshore installations, characterized in that the remaining lighting groups are connected to a switch actuator (35). The method according to claim 1,
The central controller 40 stores and executes a power saving algorithm for switching some lights 10 of the target area between maximum brightness, medium brightness, and light off in response to human movement, change of day and night, and change of season. Integrated remote lighting control system for ships and offshore facilities. The method according to claim 1,
The central controller (40) monitors abnormal conditions in addition to turning on and off the lights (10) over the network and displays them on the monitor (43) Integrated remote lighting control system for ships and offshore facilities. The method according to claim 1,
The integrated remote lighting control system for ships and offshore facilities, characterized in that the central controller (40) reflects the power saving information changed through the network-connected local controller (50) in the power saving algorithm.

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