KR102056752B1 - A drawing data system for collecting geographical information with connecting leveling device - Google Patents

Abstract

The present invention relates to a geodetic surveying data system which installs a geodetic surveying aid facility including a tripod function near a statistically frequently used national level point located in a high-altitude area to allow a geodetic surveying worker to move a total station and a staff only as needed to a corresponding location of the high-altitude area and then perform accurate geodetic surveying based on the corresponding national level point. The geodetic surveying data system collects geographic information by level survey instrument connection and comprises a housing, a lifting/lowering link, a drive motor, a support plate, a total station, a self-generation device, a power supply connector, a cylinder power connector, a total station power connector, a signal receiving unit, a storage unit, a control unit, a wireless communication module, a national level point usage situation integration management server, a user smart terminal, and a map information management device.

Description

Geodetic surveying system for leveling {A drawing data system for collecting geographical information with connecting leveling device}

The present invention relates to a geodetic surveying system for level surveying in the field of geodetic surveying technology, and more particularly, by installing a geodetic survey help facility including a tripod function in the vicinity of a national level point which is located at high altitudes and is frequently used statistically. Through this, it is related to the geodetic surveying system for level surveying, which allows the operator of the geodetic survey to move the total station and, if necessary, the staff only to the corresponding position in the highlands, and then perform more accurate geodetic survey based on the national level point.

In general, in order to produce and calibrate digital maps used in GIS, aerial photographs are taken of a certain area, and aerial photographs are made by data of aerial photographs acquired at this time.

After the digital map is produced through the above-described process, aerial photography is again performed at regular intervals to newly produce aerial photographing information, and through this process, the digital map based on the existing aerial photographing information is corrected or updated.

At this time, if an error occurs between the coordinates of the feature or artificial structure of the existing digital map to be calibrated (updated) and the coordinates of the recorded feature or artificial structure of the newly produced aerial photographing information, the error is displayed in the existing digital map. It was difficult to determine whether or not there was an error in newly produced aerial photography information.

Therefore, the point where the error is generated should be measured to correct the error. To accurately measure the measurement point, a total station is generally used.

Briefly, the total station is a form in which an electronic theodolite and an electro-optic instruments (EDM) are integrated into one device.

The total station includes a vertical angle detector for measuring the vertical angle caused by the vertical movement of the telescope, a horizontal angle detector for measuring the horizontal angle caused by the left and right rotation of the main body, a distance measuring unit for measuring the distance from the center of the main body to the prism, and the horizontal of the main body. It is a tilting sensor that measures and corrects, and is divided into four configurations.

In addition, when collecting geographic information through the total station, geodetic surveying is usually performed based on coordinates of a national level point.

The national level point is a reference point of the vertical position, and the elevation of the national level point is measured by direct leveling along the line based on the level origin.

These national level points are divided into 1st level points buried along the 1st level line and 2nd level points buried along the 2nd level line. The level of the national level points corresponds directly to the accuracy of the measured value.

Explaining the use of national level points, a project operator in a specific area will receive and use a national level scorecard from the National Geographic Information Institute that records the location of the national level points in the area where the project is performed.

However, the above-mentioned national level points cannot be installed in consideration of the convenience of the operator who performs the geodetic survey work, and the area where the error occurs between the existing digital map and the newly produced aerial photographing information is also limited to the region where the geodetic survey work is easy for the operator. In fact, a considerable number of national level points are installed at high altitudes, such as mountainous terrain, and at the same time, geodetic survey work is based on the national level points of these high altitudes.

As a result, it is difficult for the surveyor to move the surveying equipment such as total stations and tripods to near the national level located in the highlands, and at the same time, the workers who have consumed physical force for transporting the surveying equipment have less concentration in the surveying work. Can be.

In addition, in mountainous terrain, it is not easy to keep the tripod horizontal due to the rough ground, which is more burdensome for the physically tired worker as described above.

In addition, among the national level points located in the highlands, there will be national level points where geodetic surveys occur frequently based on them. Using the data as needed will help to make geodetic work more efficient.

Republic of Korea Patent Registration No. 10-1249913 (2013.03.27.) Geodetic data system dedicated to level instrument access for collecting geographic information " Republic of Korea Patent Registration No. 10-1116190 (2012.02.07.) "Geodetic data management system through a level instrument for collecting terrain information"

The present invention has been invented to solve the above problems, the object of which is to install a geodetic survey help facility including a tripod function in the vicinity of the national level point that is located at high altitude and statistically frequently used by the worker of the geodetic survey (A) to provide a geodetic surveying system for level surveying, in which a total station and, if necessary, the staff are moved to the relevant location in the highlands and then more accurate geodetic surveys can be carried out based on the national level point.

In addition, the present invention is located in the high ground and equipped with the main components in the vicinity of the statistically frequently used national level point so that the operator of the geodetic survey can immediately use at the geodetic surveying site without moving most of the equipment required for the geodetic survey In addition to providing geodetic surveying aids and determining the availability of geodetic surveying aids according to the frequency of use of the relevant national level points, it is possible to efficiently manage the availability of geodetic surveying aids by country level points in the highlands. It is to provide a geodetic surveying system for level surveying that collects geographic information by connecting to an instrument.

Characteristic configuration of the present invention for achieving the above object is installed adjacent to the national level point, the cover is coupled to the state capable of rotating more than 180 degrees at the top to open and close the receiving space through the rotation and the visual from the outside A housing including a light emitting unit having a wireless communication unit for receiving an external operation signal while being installed in a state capable of being checked; An elevating link installed at an inner side of the housing, the elevating link having an upper portion ascended and rotated from a hinge installed at a center thereof; A screw shaft rotatably installed on a driving motor to raise and lower the lifting link and having female threads and male threads respectively formed on both sides thereof based on augmentation; A guide plate installed at an upper end of the elevating link to be in contact with a bottom surface thereof, and elevating to an elevated height in association with an up and down movement of the elevating link, the support plate having a fixing portion for fixing an object on an upper surface thereof; A support part corresponding to the fixing part of the support plate and detachably coupled to an upper surface of the support plate through a coupling between the support part and the fixing part of the support plate, and a first connection part for supplying power from the outside; A total station including a second connection unit for receiving various data and electrical signals from the outside; A first power generation device including a solar cell that is installed adjacent to the housing and converts sunlight into electrical energy; and a second power generation device that generates power using wind speeds generated around the installation location; and the first power generation device; A self-powered apparatus including a rechargeable battery connected in parallel to a second power generator to charge electrical energy generated by the first power generator and the second power generator, respectively; A power supply connector electrically connected to the rechargeable battery of the self-generating device and installed in the accommodating space inside the main body via a first power supply line extending to the inner accommodating space of the housing; A cylinder power connector that is electrically connected to the power supply of the lifting cylinder and is electrically connected to the tip of a power line extending to the outside of the housing to supply power to the lifting cylinder through electrical connection with the power supply connector. ; It is installed on the support plate via a second power supply line which is electrically connected to the rechargeable battery of the self-generating device and extends to the support plate, and supplies power to the total station through an electrical connection with the first connection part of the total station. A total station power connector; A signal receiver installed at the support plate and electrically connected to a second connection part of the total station to receive survey values and various data processed by the total station during geodetic survey of the total station; A storage unit installed on the support plate and storing data and various other data received through the signal receiving unit; The national level point use information generated after generating the national level point use information by synchronizing the factual information of the national level point and the unique identification code of the national level point to the information received every time a signal is received from the signal receiving unit. A controller configured to output a signal and store signals received from the signal receiver in the storage unit; A wireless communication module for transmitting the national level point use information output from the control unit to an external server through a communication network; Receives country level point usage information transmitted through the wireless communication module through the communication network, and uses the country level point for mapping the unique identification code and the country level point usage information generated and transmitted by the controller for each country level point and storing them in a table form. Status integrated management server; A user smart terminal having a remote control function for remotely controlling the light emitting unit and the elevating cylinder by mounting a light emitting unit on / off operation installed in the cover and a geodetic survey dedicated application for operating the elevating cylinder; A geographic information DB for storing imaged topographical information, a geographic information DB for storing geographic information that is numerical information corresponding to the topographical information, and geographic information including geodetic survey data based on country level points transmitted from the total station; A geographic information of the geographic information DB based on geographic information transmitted from the total station when a difference between the collected information comparing module previously stored in the information DB and the collected information comparing module compares the collected information comparing module with a reference value. And an update module for modifying and updating a digital map, and a digital map output module for synthesizing the geographical information stored in the geographical information DB and the geographical information stored in the geographical information DB to output a numerical map.

As described above, the present invention installs a geodetic survey help facility including a tripod function in the vicinity of a national level that is statistically frequently used at high altitudes, whereby a geodetic surveyor has a total station and, if necessary, a staff station in the highlands. After moving to that location, more accurate geodetic surveys can be performed based on the national level points.

In addition, it is possible to move the major components in the vicinity of the national level point that is located at high altitude and statistically frequently used, so that the surveyor's workers can immediately use them at the surveying site without moving most of the equipment required for the surveying. In addition to providing geodetic surveying aids and determining the availability of geodetic surveying aids at all times according to the frequency of use of the relevant national level points, it is possible to efficiently manage the availability of geodetic surveying aids at each national level in the highlands.

1 is a block diagram conceptually showing a geodetic survey data system for collecting geographic information with a level instrument connection according to the present invention.
Figure 2 is a block diagram showing the overall configuration of a geodetic survey data system for collecting geographic information with a level instrument connection in accordance with the present invention.
3 and 4 are cross-sectional views showing the structure and operation of the main portion of the geodetic survey data system for collecting geographic information by connecting the level instrument according to the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Prior to the description of the present invention, the following specific structures or functional descriptions are merely illustrated for the purpose of describing embodiments according to the inventive concept, and the embodiments according to the inventive concept may be embodied in various forms, It should not be construed as limited to the embodiments described herein.

In addition, embodiments in accordance with the concepts of the present invention can be variously modified and have a variety of forms, specific embodiments will be illustrated in the drawings and described in detail herein.

1 is a schematic diagram showing a geodetic survey data system for collecting geographic information in a level instrument connection according to the present invention, Figure 2 is a total of a geodetic survey data system for collecting geographic information in a level instrument connection according to the present invention 3 and 4 are cross-sectional views showing the structure and operating state of main parts in a geodetic survey data system for collecting geographic information by connecting to a level instrument according to the present invention.

The present invention is to install a help facility (S) for geodetic survey of the total station in the vicinity of the country level point (A) located in the highlands, and at the same time such a help facility (S) is used in conjunction with the total station of the corresponding country level point (A) The use fact information is transmitted to the remote country level point use status integrated management server 600 through a communication network.

Accordingly, the national level point use status integrated management server 600 according to the use fact information of the corresponding national level point (A) transmitted from the geodetic survey help facility (S) for each country level point (A) of the highlands, A country that can analyze the usage status, such as the frequency of use of each, and the main configuration of the geodetic surveying aid (S), which is thus movable, by configuring the main configuration in a movable form among the overall configuration of the geodetic survey aid (S) Level point use status According to the usage status of the high-level country level point (A) of the integrated management server 600 can be installed efficiently around the country level point (A) of frequent use.

On the other hand, with reference to Figures 2 to 4 will be described in detail the configuration of a geodetic survey data system for collecting geographic information in the level instrument connection according to the present invention.

Geodetic survey data system for collecting geographic information in connection with the leveling instrument according to the present invention, the housing 210, the lifting link 240, the support plate 230, the total station 100, the self-generating device 300, power Integration of supply connector 350, cylinder power connector 243, total station power connector 231, signal receiver 232, storage 260, controller 250, wireless communication module 270, national level usage status It comprises a management server 600, the user smart terminal 400, the map information management device 500.

A cover 212 is installed on an upper surface of the housing 210, and a light emitting part 214 is installed on the cover 212.

The housing 210 is installed adjacent to the national level point (A), the cover 212 is coupled to the top of the housing 210 in a state capable of rotation of more than 180 degrees and through the rotation of the inside of the housing 210 Open and close the receiving space (211).

That is, the cover 212 is coupled to and rotated through the hinge coupling portion 213 that enables rotation of 180 degrees or more on the upper end of the housing 210 to open or close the receiving space 211 of the housing 210.

And the light emitting unit 214 is installed on the cover 212 in a state that can be visually confirmed from the outside, the light emitting unit 214 is provided with a wireless communication unit (not shown) for receiving an external operation signal.

In detail, the light emitter 214 is turned on / off through a control signal transmitted from the user smart terminal 400, and the light emitter 214 is wirelessly transmitted from the user smart terminal 400. And a wireless communication unit (not shown) for receiving the control signal.

The elevating link 240 is installed inside the housing 210, and screw shafts 241 are screwed to both sides of the lower side, and the screw shaft 241 has a female screw portion 241a at one side of the center. A male screw portion 241b is formed on the other side, and the lifting link 240 is raised when rotated in the forward direction and the lifting link 240 is lowered when rotated in the reverse direction.

As the support plate 230 is installed on the upper end of the elevating link 240 via the guide roll 244, the elevating link 240 is operated to work up and down.

And the support plate 230 is provided with a fixing portion 233 for fixing the object to be supported on the upper surface. In other words, the fixing part 233 corresponding to the fixing part 130 of the total station 100 is provided on the upper surface of the supporting plate 230, such that the fixing part 233 of the supporting plate 230 and the total station ( The total station 100 is detachably supported on the upper surface of the support plate 230 through the fixing part 130 of the 100.

The total station 100 has a supporting portion 130 corresponding to the fixing portion 233 of the supporting plate 230 as mentioned in the description of the supporting plate 230 described above, and the fixing portion 233 and the supporting portion Through the coupling of the 130, the total station 100 is detachably coupled to the upper surface of the support plate 230.

The total station 100 includes a first connection unit 110 for supplying power from the outside and a second connection unit 120 for receiving various data and electrical signals from the outside. The overall configuration of 100) is the same as a conventional total station configuration used for the existing geodetic survey, and thus, detailed description of the total configuration of the total station 100 will be omitted in the present invention.

Self-generating device 300 is installed adjacent to the housing 210, such a self-generating device 300 is the first power generation device 310 and the installation position of the solar cell to convert the solar light into electrical energy It includes a second power generation unit 320 for generating power using the wind speed generated in the vicinity.

In addition, the self-generating device 300 is connected in parallel to the first power generator 310 and the second power generator 320 to charge the electric energy generated by the first power generator 310 and the second power generator 320, respectively. It includes a rechargeable battery 330.

The power supply connector 350 is electrically connected to the rechargeable battery 330 of the self-generating device 300 and is accommodated through the first power supply line 340 extending to the inner accommodating space 211 of the housing 210. 211 is installed.

The cylinder power connector 243 is electrically connected to the power supply unit of the elevating cylinder 240 and is electrically connected to the front end of the power line 242 that can extend to the outside of the housing 210.

That is, the cylinder power connector 243 performs a function of supplying power to the lifting lowering cylinder 240 through an electrical connection with the power supply connector 350.

The total station power connector 231 is installed on the support plate 230 through a second power supply line 234 electrically connected to the rechargeable battery 330 of the self-power generator 300 and extending to the support plate 230. do.

The total station power connector 231 functions to supply power to the total station 100 through electrical connection with the first connection unit 110 of the total station 100.

The signal receiver 232 is installed on the support plate 230, and the signal receiver 232 is electrically connected to the second connection unit 120 of the total station 100, so that the survey values of the total station 100 are measured. And various data processed by the total station 100.

The storage unit 260 is installed on the support plate 230, and the storage unit 260 is installed for storing data and various other data received through the signal receiver 232.

The control unit 250 is installed on the support plate 230, the control unit 250 is a real-time used fact information of the country level point (A) and the country level point (A) to the information received every time a signal is received from the signal receiving unit 232 Synchronize unique identification code of) to generate country level usage information.

In addition, the controller 250 outputs the state level usage information thus generated to the wireless communication module 270, and the controller 250 stores the signals received from the signal receiver 232 in the storage 260.

The wireless communication module 270 transmits the national level point usage information output from the control unit 250 to an external server through the communication network, that is, the national level point usage integrated management server 600.

The state level point usage integrated management server 600 receives the state level point usage information transmitted through the wireless communication module 270 through a communication network, and the state level point usage integrated management server 600 uniquely identifies each state level point. The code and the control unit 250 maps the national level point usage information generated and transmitted and stores it in a table form.

That is, based on the unique identification code of the national level point, information such as the total cumulative number of use of each country level point, the cumulative number of times of use for a certain period of time, and the date and time of use for the latest period are mapped with the corresponding national level point. .

In addition, the user smart terminal 400 is equipped with a geodetic surveying dedicated application 410 for the on / off operation and operation operation of the drive motor 245 for the light emitting unit 214 installed on the cover 212.

Accordingly, the user smart terminal 400 functions as a remote controller for remotely controlling the driving motor 245 to operate the light emitting unit 214 and the smart elevating link 240 through the execution of the geodetic surveying-only application 410. do.

When the driving motor 245 is driven in the forward direction, the screw shaft 241 having the female threaded portion 241a and the male threaded portion 241b formed on both sides of the center is rotated and pulled to the center at the lower end of the lifting link 240. The lifting link 240 is moved around the hinge 246 while the upper end is moved to the center.

When the guide roll 244 is rotated when the upper end of the lifting link 240 is collected, the support plate 230 is raised.

On the other hand, the map information management device 500 is configured to include a terrain information DB 510, geographic information DB 520, collection information comparison module 530, update module 540, digital map output module 550. .

The terrain information DB 510 stores the imaged terrain information, and the geographic information DB 520 stores geographic information that is numerical information corresponding to the terrain information.

The collected information comparison module 530 compares geographic information including geodetic survey data based on the national level point A transmitted from the total station 100 with corresponding existing geographic information previously stored in the geographic information DB 520.

The update module 540 modifies the geographic information of the geographic information DB 520 based on the geographic information transmitted from the total station 100 when a difference of more than the reference result of the collection information comparison module 530 occurs. Update

The numerical map output module 550 synthesizes the geographic information stored in the geographic information DB 520 and the geographic information stored in the geographic information DB 510 to complete the numerical map.

As described above, the geodetic survey data system that collects geographic information by accessing the level instrument according to the present invention, the geodetic survey help facilities including a tripod function in the vicinity of the national level point that is located in the highlands and statistically frequently used This enables operators of geodetic surveys to move the total station and, if necessary, staff only to the corresponding locations in the highlands, and to perform more accurate geodetic surveys based on the national level points.

In addition, it is possible to move the major components in the vicinity of the national level point that is located at high altitude and statistically frequently used, so that the surveyor's workers can immediately use them at the surveying site without moving most of the equipment required for the surveying. In addition to providing geodetic surveying aids, it is also possible to efficiently manage the availability of geodetic surveying aids at high-level national level points by determining whether the geodetic survey aids are kept on a regular basis according to the frequency of their use.

100: total station 110: first connection portion
120: second connection portion 130: support portion
210: housing 211: accommodation space
212 cover 213 hinge coupling portion
214: light emitting unit 230: support plate
231: total station power connector 232: signal receiver
233: fixing part 234: second power supply line
240: lifting link 241: screw shaft
242 power line 243 cylinder power connector
244: guide roll 245: drive motor
246 hinge 250: control unit
260: storage unit 270: wireless communication module
300: self-generating device 310: first power generating device
320: second generator 330: rechargeable battery
340: first power supply line 350: power supply connector
400: user smart terminal 410: geodetic survey dedicated application
420: touch screen 500: map information management device

Claims (1)

It is installed adjacent to the national level point, the cover is coupled to the state that can be rotated more than 180 degrees at the top, and the cover to open and close the receiving space through the rotation and the cover is installed in a state that can be visually confirmed from the outside and at the same time receives an external operation signal Housing including a light emitting unit provided with a wireless communication unit for;
An elevating link installed at an inner side of the housing, the elevating link having an upper portion ascended and rotated from a hinge installed at a center thereof;
A screw shaft installed rotatably on a drive motor to raise and lower the link, and having a female screw portion and a male screw portion formed on both sides thereof based on the increase;
A guide plate installed at an upper end of the elevating link to be in contact with a bottom surface thereof, and elevating to an elevated height in association with an up and down movement of the elevating link, the support plate having a fixing portion for fixing an object on an upper surface thereof;
A support part corresponding to the fixing part of the support plate and detachably coupled to an upper surface of the support plate through a coupling between the support part and the fixing part of the support plate, and a first connection part for supplying power from the outside; A total station including a second connection unit for receiving various data and electrical signals from the outside;
A first power generation device including a solar cell that is installed adjacent to the housing and converts sunlight into electrical energy; and a second power generation device that generates power using wind speeds generated around the installation location; and the first power generation device; A self-powered apparatus including a rechargeable battery connected to a second power generator in parallel to charge electrical energy generated by the first power generator and the second power generator, respectively;
A power supply connector electrically connected to the rechargeable battery of the self-generating device and installed in the accommodating space inside the housing through a first power supply line extending to the inner accommodating space of the housing;
A cylinder power connector that is electrically connected to the power supply of the lifting link and is electrically connected to the tip of a power line extending to the outside of the housing to supply power to the lifting link through an electrical connection with the power supply connector. ;
It is installed on the support plate via a second power supply line which is electrically connected to the rechargeable battery of the self-generating device and extends to the support plate, and supplies power to the total station through an electrical connection with the first connection part of the total station. A total station power connector;
A signal receiver installed at the support plate and electrically connected to a second connection part of the total station to receive survey values and various data processed by the total station during geodetic survey of the total station;
A storage unit installed on the support plate and storing data and various other data received through the signal receiving unit;
The national level point use information generated after generating the national level point use information by synchronizing the factual information of the national level point and the unique identification code of the national level point to the information received every time a signal is received from the signal receiving unit. A controller configured to output a signal and store signals received from the signal receiver in the storage unit;
A wireless communication module for transmitting the national level point usage information output from the control unit to an external server through a communication network;
Receives country level point usage information transmitted through the wireless communication module through the communication network, and uses the country level point for mapping the unique identification code and the country level point usage information generated and transmitted by the controller for each country level point and storing them in a table form. Status integrated management server;
A user smart terminal having a remote control function for remotely controlling the light emitting unit and the lifting cylinder by mounting a light emitting unit on / off operation installed in the cover and a geodetic survey dedicated application for operating an operation of the elevating link;
A geographic information DB for storing imaged geographic information, a geographic information DB for storing geographic information corresponding to geographic information, and geographic information including geodetic survey data based on country level points transmitted from the total station; A geographic information of the geographic information DB based on geographic information transmitted from the total station when a difference between the collected information comparing module previously stored in the information DB and the collected information comparing module compares the collected information comparing module with a reference value. A leveling instrument including an update module for modifying and updating a digital map, and a digital map output module for synthesizing the geographical information stored in the geographical information database and the geographical information stored in the geographical information DB to output a numerical map. Geodetic system for level surveying, which collects geographic information by connection.

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