KR101958269B1 - Intelligent equipment installed in marine resource production system for remote monitoring - Google Patents

Abstract

The present invention relates to a design-measurement comparison algorithm-embedded intelligent apparatus installed in a marine resource production system for remote monitoring. More specifically, the intelligent apparatus is installed in a marine resource production system to monitor the marine resource production system and surrounding environments in an extreme marine environment, such as typhoon, hurricane, and the like. In other words, the intelligent apparatus compares and analyzes an actual measurement value and a normal design value to provide the result to a remote place, thereby reducing a time equal to or longer than one month required, in a conventional method, for a remote engineer who receives only the measurement value, and performs analysis and evaluation after normalization based on insufficient measurement values to check a fatigue failure of a part forming the marine resource production system in the extreme marine environment. According to the present invention, the intelligent apparatus comprises a casing box and a subframe.

Description

TECHNICAL FIELD [0001] The present invention relates to an intelligent device installed in a marine resource production system for remote monitoring,

The present invention relates to an intelligent device with a design-metric comparison algorithm installed in a marine resource production system for remote monitoring.

Specifically, it is installed in the marine resource production system to monitor the marine resource production system and the surrounding environment remotely in extreme marine environment such as typhoon, hurricane, etc., and compares the actual measured value with the normal design value and analyzes And provides the result to the remote site,

The analysis and evaluation after the normalization work based on the measurement value that the remote engineer who is provided only the existing measured value is insufficient and the time for checking the fatigue destruction of the part constituting the marine resource production system in the extreme marine environment To an intelligent device installed in a marine resource production system for remote monitoring.

Marine resource production systems generally refer to plant facilities that are installed at the ocean and collect or produce resources that can only be harvested from the ocean.

Such a marine resources production system is configured to be able to be monitored at a remote site as much as it is installed in the ocean. Conventional technology is designed to perform general functions of collecting information acquired through an instrument and transferring it to a remote place on land.

In addition, the remote site that receives the information requires the engineer to be employed separately to analyze and evaluate the information.

On the other hand, typhoons and hurricanes often appear more frequently in the ocean than on land, and the scale and damage are considerably higher than in general land. However, it is not a problem because there is usually no room for damage, but in the case of offshore marine resource production systems, natural disasters cause serious damage in the vicinity.

Accordingly, when the natural disaster is predicted, the workers are evacuated. In this case, all the operations of the marine resources production system are stopped, and the conditions for maintenance are not provided. Therefore, The marine resources production system is receiving the same.

Generally, in the case of a marine resources production system, when the worker is evacuated in this way, it is necessary to store all the measured information based on a power of about 7 days.

However, if the return of the worker is delayed due to the continuous deterioration of the climate, the information after 7 days will not be measured due to the power supply failure and management failure, and the measurement information from when the power is not supplied to when the worker is returned can not be secured do.

However, in the past, based on the information measured 7 days, the engineer performs normalization based on the measured information (damage caused by natural disasters, fatigue damage, etc.) and predicts information during the unmetered period. However,

This not only lowers the accuracy, but also requires a month or more to analyze and evaluate through normalization.

Accordingly, the present applicant has come to draw attention to a device capable of solving the above-mentioned problems.

Regarding the management technology of an offshore plant (marine resource production system), a remote monitoring and control system of an offshore plant emergency stop system of Prior Art No. 10-1881224 (prior art 1) is described,

Japanese Patent Application Laid-Open No. 10-1729725 discloses a real-time monitoring system for ships and offshore plants (prior art 2)

In Japanese Patent Application Laid-Open No. 10-2017-0050625, there is described an IoT-based plant facilities remote monitoring system (prior art 3)

In Japanese Patent Application Laid-Open No. 10-2015-0090948, a video complex type remote control system for offshore plants (prior art 4) is described.

Although the above technologies describe technologies that can be remotely monitored for offshore plants, they are implemented as a separate device for exclusive use and are not related to the technology for installing on a offshore plant.

Particularly, in the case of the prior art 4, the image hybrid type technology is described, and the present invention proposed by the present applicant is similar to the present invention in that the image is used, and the analysis is completed in a separate apparatus and is provided to a remote site There is a difference in that it can not.

In addition, since communication paths for transmitting / receiving information to / from a remote place are different from each other, communication can not be smoothly performed in a bad climate and control can not be smoothly performed.

Patent Registration No. 10-1881224 (Bulletin issued on July 23, 2018) Patent Registration No. 10-1729725 (Announcement of Apr. 24, 2014) Published Japanese Patent Application No. 10-2017-0050625 (Nov. Published Japanese Patent Application No. 10-2015-0090948 (Aug.

It is an object of the present invention to provide a system for monitoring marine resources production system and surrounding environment remotely in an extreme marine environment such as a typhoon and a hurricane, And provides the results to the remote site,

The analysis and evaluation after the normalization work based on the measurement value that the remote engineer who is provided only the existing measured value is insufficient and the time for checking the fatigue destruction of the part constituting the marine resource production system in the extreme marine environment And to provide an intelligent device installed in a marine resources production system for remote monitoring.

According to an aspect of the present invention, there is provided an intelligent device installed in a marine resource production system for remote monitoring,

In an intelligent device installed in a marine resource production system and comprising an enclosure and a subframe,

In the housing,

An accelerometer and a gyro sensor for measuring the behavior of the marine resource production system, a plurality of solar panels for charging sunlight, A satellite and mobile antenna for communication and an antenna for interworking with a web server, a DGPS for positioning the marine resource production system, and a panning, tilting and zooming function for acquiring a general image and an infrared image or acquiring an image And a camera device that can be used is provided.

At this time,

Two batteries are provided,

One of the batteries stores the power normally operated as the power generated from the solar panel and the other stores the auxiliary power,

The auxiliary power can be operated for a predetermined time even if the normal power is not operated.

Further, the enclosure may further include an analysis unit and storage,

The storage device

The 'normal design value', which is a normal form of the components constituting the marine resource production system, is previously stored in the measurement values to be normally measured in the weather vane, anemometer, pressure gauge, hygrometer, thermometer and gyro sensor,

The analyzing unit,

'Comparing and analyzing the measured values actually measured by the weather vane, anemometer, pressure gauge, hygrometer, thermometer and gyro sensor and the' actual measured value ', which is the type of the component confirmed through the camera device, .

In addition,

Receives and transmits information to and from a remote site through satellite communication and mobile communication, and receives control signals from a remote site through web communication.

Further, the subframe is fastened with the housing and the bolt.

According to the intelligent device installed in the marine resource production system for remote monitoring according to the present invention,

First, unlike existing systems, which simply send monitored data to the land, comparing the measured data with the design data, the field worker and the field engineer have the effect of supporting quick decision making without having to wait more than one month,

Secondly, it has the effect of not needing to operate a separate organization for malaise,

Third, it provides the necessary result screen for the worker, and the land-based engineer can evaluate only the evaluation result, so that the inspection and maintenance priority can be determined based on the evaluated result, and the actual support of asset integrity management of the data base is supported. .

As an embodiment, the present invention can be utilized as a safety post for monitoring the surrounding environment in a marine plant, a petrochemical plant, or a power plant without a person, and can be used for safety monitoring of a floating LNG power plant , And can also be used as a device for monitoring the operation of unmanned vessels.

1 shows an intelligent device installed in a marine resource production system for remote monitoring according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor can properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and drawings are only the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents And variations are possible.

Before describing the present invention with reference to the accompanying drawings, it should be noted that the present invention is not described or specifically described with respect to a known configuration that can be easily added by a person skilled in the art, Let the sound be revealed.

The present invention relates to an intelligent device with a design-metric comparison algorithm installed in a marine resource production system for remote monitoring.

Specifically, it is installed in the marine resource production system to monitor the marine resource production system and the surrounding environment remotely in extreme marine environment such as typhoon, hurricane, etc., and compares the actual measured value with the normal design value and analyzes And provides the result to the remote site,

The analysis and evaluation after the normalization work based on the measurement value that the remote engineer who is provided only the existing measured value is insufficient and the time for checking the fatigue destruction of the part constituting the marine resource production system in the extreme marine environment To an intelligent device installed in a marine resource production system for remote monitoring.

More specifically, the present invention will be described with reference to the accompanying drawings.

1 shows an intelligent device installed in a marine resource production system for remote monitoring according to the present invention.

The intelligent device according to the present invention can be installed in a marine resource production system and can measure the state (behavior state) and marine environment (wind direction, wind speed, etc.) of a marine resource production system. Satellite communication, and mobile communication, so that communication can be performed even if the climate of the ocean is in a bad condition. In addition, remote control of the intelligent device can be performed using web communication, thereby enabling control of the intelligent device So that it can be smoothly performed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS According to FIG. 1 of the accompanying drawings, an intelligent device mainly includes an enclosure and a subframe.

The enclosure is provided with at least two solar panels for charging sunlight, and includes a satellite and mobile antenna for communication and an antenna for interworking with a web server.

In addition, DGPS (Differential GPS) for determining the position of marine resources production system can be equipped with a satellite based augmentation system (SBAS) technology. And is widely known, so a detailed description can be omitted.

Also, the intelligent device may be equipped with a weather vane and anemometer for measuring the wind direction and wind speed of the marine environment, and a six-degree-of-freedom three-axis gyro sensor and an accelerometer for measuring the tilt of the marine resource production system At this time, the behavior of the marine resource production system can be confirmed through the inclination measurement of the marine resource production system and the position measurement through the DGPS. If you add up to the measured values according to wind direction and wind speed, you can see more accurate behavior.

In addition, a barometer, a hygrometer, and a thermometer for measuring the marine environment around the marine resources production system may be provided as sensors.

In addition, the intelligent device may be provided with a camera device installed for the purpose of analyzing fatigue failure of a component constituting a marine resource production system, wherein the camera device is implemented by any one of infrared camera, thermal camera and digital camera To obtain a general / infrared image for a marine resource production system, or to acquire a captured image.

At this time, the camera device can be implemented to be capable of panning, tilting, and zooming functions.

In addition, the battery of the intelligent device may be equipped with two batteries, one of which stores the power generated through the solar panel, and the other one of which is an auxiliary power that is generated by normal power, wave power, .

In operation of these two batteries, the intelligent device is operated by the electric power generated and stored through the solar panel in the normal situation. However, when the occupants who board the marine resources production system due to the deterioration of the surrounding environment are evacuated for a long time, The remaining batteries stored in the auxiliary storage are further operated to cover the power so that even if solar charging is not possible due to the deterioration of the solar power, the power can be operated for about 15 days. Therefore, There is an advantage that the problem can be solved.

These two battery operations can be made to function including the battery charging controller of the enclosure shown in FIG. 1 and the battery operating unit not shown in the drawing.

In addition, one side of the housing of the intelligent device may include design-measurement analysis evaluation software (hereinafter referred to as "analysis unit"), which further comprises a separate storage device (storage) It stores the measurement values that should normally be measured in the weather vane, anemometer, pressure gauge (barometer), hygrometer, thermometer, gyro sensor, etc. and the normal form of the parts constituting the marine resource production system (hereinafter referred to as "normal design value" .

That is, the analyzing unit analyzes the measurement values actually measured by the weather vane, anemometer, pressure gauge (barometer), hygrometer, thermometer, gyro sensor, and the type of the component confirmed through the camera device (hereinafter referred to as 'actually measured value') The normal design values are compared and analyzed to see how they differ.

This analysis information is transmitted to the terminal held by the manager at the remote site (satellite communication and mobile communication).

In this case, for example, when the design value of the wind direction and the wind speed for maintaining a stable marine resource production system is Bkm / h in the direction A, the actual measured value is a 'direction b' km / h < / RTI >

Another example may be the extent to which a column frame of a crane, one of the components of a marine resource production system, is corrupted by having a morphological difference from the normal design value when viewed with an image or a captured image Analysis).

In addition, the above-described solar panel can be adjusted by adjusting the angle of a motor, a gear, and a hinge on one side while applying a conventional solar panel, so that the sun can be tracked and charged, The tracking of the sun on the panel is variously known with respect to tracking based on a predetermined period or sunlight, and therefore, a detailed description thereof will be omitted.

However, as a difference from the conventionally known technology, the control of the intelligent device can be controlled by connecting to the intelligent device via the web as described above, so that a graphical user interface (GUI) for controlling the angle of the solar panel is implemented Thus, the administrator can connect the web server to the terminal from a remote place, and individually control the plurality of solar panels. It is obvious to a person skilled in the art that a separate web server exists for this purpose.

Through this, even if the climate of the marine environment becomes bad condition and the workers are withdrawn (evacuated) and the solar battery is not properly charged due to the bad weather, the administrator who checked the charging status based on the GUI confirms the charge state, And has the advantage of enabling angle adjustment of the panel.

It should be understood, of course, that the exemplary web-based remote control described above is illustrated for a solar panel, but that all control that can be predicted through this specification can be performed based on the GUI.

Meanwhile, the subframe is coupled to the lower surface of the enclosure by bolts, not by welding, so that the enclosure can be engaged and fixed from one side of the marine resources production system. In addition, the subframe may be made of a material satisfying the IP66 rating.

At this time, the bracket and the subframe may be bolted or welded together by integrally bending the bracket to one side of the subframe for bolt fastening, and the other side may be bolted to the bracket.

Such a subframe may be configured as shown in [Table 1] and [Table 2] depending on design conditions.

First, a long hole is formed in the bracket to allow the bolt to penetrate, and the bolt allows the fastening part to be coupled to the threaded column area. To this end, a through hole is formed in the fixing part through which the bolt passes, and a thread corresponding to the thread of the bolt is formed in the through hole.

At this time, the fixing portion is bent and inserted into the elongated hole with the bolt in a state of being deflected toward the lower left side and the upper right side with respect to the bolt with respect to the elongated hole and coupled to the bolt.

Thereafter, as the bolt is rotated, the fixed part also rotates together with the left lower side moving upward and the right upper side moving in the right lower direction within the slot, and this is fixed because the bolt is firmly coupled to the slot .

However, as shown in [Table 2], a step is formed at one side of the column region of the bolt, so that when the bolt is finally joined, the clamping force can be further strengthened as the step is caught at one side of the fixing part.

Further, referring to [Table 1], the liquid bag may be inserted into the region outside the region corresponding to the fixed portion on the inside of the long hole, or may be integrally formed by being attached to the inner surface of the long hole. Preferably, May be desirable.

Such a liquid bag is preferably a bag which is sealed in a state of containing a liquid therein, and the material of the bag is preferably made of a material such as silicone which is not damaged. Further, when the liquid bag is inserted, an adhesive for silicone may be applied to the inner surface of the slot, and then the liquid bag may be inserted to increase the fixing.

According to this structure, when a shock is applied to a marine resource production system or an intelligent device, the bolt can flow in the slot together with the fixing portion, so that the impact can be dispersed and mitigated.

However, if the bolt moves easily in the long hole, the damage of the intelligent device installed in the marine resource production system installed in the ocean may be worried. Therefore, the flow of the bolt and the fixing portion is secured by the liquid bag, When the liquid pouch is pressed according to the flow of the bolt and the fixing part, the liquid contained in the liquid is expanded, and when the bolt and the fixing part return to the original position, It is possible to prevent the possibility of breakage.

These enclosures are made of glass fiber material and are made of NEMA 4X, IP66 and UL grade glass fiber, and are excellent in dustproofing and waterproofing and effective for explosion proof.

However, for the purpose of enhancing the explosion-proof function of the enclosure, the cross-sectional shape of the enclosure in the lateral direction may be configured as shown in [Table 3] according to the design conditions.

Referring to [Table 3], a cross-sectional view of a housing is shown in which a rectangular box is opened by breaking one side, bent to the inside, a width of the broken lower side is widened, Yellow) are supported and supported. As another example, a fan may be configured between a plurality of springs to allow the fan to flow wind from the inside to the outside.

According to such a structure, it is possible to prevent the inflow of dust from the outside, to discharge the internal dust, to have an effect of cooling by releasing heat generated inside the enclosure, So that the effect of relieving the impact can be obtained.

It is apparent that the present invention is not limited to the configuration of the drawings, as described above with reference to the drawings, only the main points of the present invention are described, and various designs can be made within the technical scope thereof.

Claims (5)

In an intelligent device installed in a marine resource production system and comprising an enclosure and a subframe,
In the housing,
- send and receive information to and from a remote site via satellite and mobile communications, receive control signals from a remote location via web communications,
A pressure gauge, a thermometer, a hygrometer, a weather vane and an anemometer for measuring the surrounding environment, an accelerometer and a gyro sensor for measuring the behavior of the marine resource production system, a plurality of solar panels for charging sunlight , A satellite and a mobile antenna for communication and an antenna for interworking with a web server, a DGPS for positioning the marine resources production system, and a panning, tilting and zooming device for acquiring a general image and an infrared image, A camera device capable of functioning is provided,
- with two batteries,
One of the batteries stores the power normally operated as the power generated from the solar panel and the other stores the auxiliary power,
The auxiliary power can be operated for a predetermined time even if the normal power is not operated,
- The enclosure further comprises an analysis unit and storage,
The storage device
The 'normal design value', which is a normal form of the components constituting the marine resource production system, is previously stored in the measurement values to be normally measured in the weather vane, anemometer, pressure gauge, hygrometer, thermometer and gyro sensor,
The analyzing unit,
'The measured values actually measured from the weather vane, anemometer, pressure gauge, hygrometer, thermometer and gyro sensor and the' actual measured value 'which is the type of the parts confirmed through the camera device are compared with the' normal design value '
- the subframe is bolted to the housing,
The enclosure is formed in a rectangular box shape, one side of which is opened to be folded into the inside of the housing, and a plurality of springs are provided and supported on the bent surface and the wide end, However,
A fan is arranged between the plurality of springs to allow the fan to flow wind from the inside to the outside of the enclosure, thereby preventing dust from entering the outside, discharging the inside dust, and releasing heat generated inside the enclosure Cooling effect and dispersing impact transmitted to the interior of the enclosure at the same time as an effect of mitigating the impact when an impact occurs, and an intelligent device installed in a marine resource production system for remote monitoring. delete delete delete delete

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