KR101915288B1 - Apparatus for geodesic surveying - Google Patents

Abstract

The present invention relates to a geodesic surveying apparatus to minimize a measured error value, which installs a leveling rod in a state to prevent an error caused by a surface condition and selectively adjusts a position to put the bottom of the leveling rod thereon at various heights in consideration of the length of the leveling rod, a surrounded wind speed, and the like, such that a fall of the leveling rod and a fixing device thereof are prevented well, the leveling rod is easily washed to show a scale of the leveling rod well, and planar coordinate and altitude information is integrally checked. According to the present invention, the geodesic surveying apparatus to minimize a measured error value comprises an altitude measurement device and a geodesic surveying data collection device to communicate with the altitude measurement device. The altitude measurement device comprises a leveling rod installation device, the leveling rod, a distance measurer, a transmitter, a leveler, and an altitude information collector. The leveling rod installation device comprises the leveling rod fixing device, a leveling rod dust removing device, first and second coupling members, a leveling rod installation height adjustment device, a reflection device, and a fall prevention device.

Description

[0001] Apparatus for geodesic surveying [0002]

The present invention can be installed in a state in which the skew of the land surface measurement technique is prevented from being error caused by the ground state and at the same time the point where the lower end of the land is placed can be selectively adjusted at various heights in consideration of the length, It is possible to more easily prevent the fall of the skeleton and its fixing mechanism, to easily wipe the skeleton so that the scale of the skeleton can be seen clearly, and to minimize the measured error value that enables the skeletal coordinate and the altitude information to be integrally confirmed And the like.

In general, surveying is done first for various civil engineering design and architectural design.

Surveying measures the horizontal distance, elevation difference and direction to determine the position of the mutual points, displays them in figures or numerical values, and refers to all activities that are stake out in the field.

In leveling, leveling is a measurement that calculates the height difference between two points using a skeleton (stiff) and a leveling machine.

Fig. 1 (Korean Patent Laid-Open No. 10-2011-0088329) illustrates a general progress of leveling. Referring to this, leveling is performed in the following order.

First, the table spinal cord is placed on the ground reference point which knows the elevation, and the machine number reads the scale scale from the first observation point, which is a certain distance away, to the level indicator.

Then, the table spinal cord is moved to the first point to set up the table, and the machine number reads the scale of the table chuck set on the first point. At this time, the elevation of the first point is obtained from the difference between the ground reference point and the scale read at the first point and the elevation of the ground reference point.

Then, the machine number moves to the second observation point behind the first point, and the table spinal cord turns the skeleton in place so that the skeleton looks at the level gauge, and the machine number reads the scale gauge as a level gauge.

Then the table spinal cord is moved to the second point to set up the table, and the machine number reads the scale of the table chuck set up at the second point. At this time, the elevation of the second point is obtained from the scale difference between the first point and the second point read from the second observation point.

In the above-described manner, the table chuck and the level gauge are continuously moved, and the elevation of each point to the target point is obtained by reading the scale by switching the direction of the table chuck and the level gauge at each point.

On the other hand, in performing the leveling work, a bird or a flywheel approaches to the periphery of the skeleton, and the number of the machine is hindered from observing the skeleton accurately, which is a factor of lowering the accuracy of the leveling work.

In addition, since it is necessary to read the scale by changing the direction of the marking chuck in place, various errors are generated depending on the state of the ground, and it is not possible to erect the marking accurately.

In addition, in the past, when the scales were not clearly visible due to the presence of dust on the surface of the table, it was necessary to wipe the surface of the table with the table having a relatively long length.

In addition, since the measured elevation information and the plane coordinates according to the elevation information can not be integrally confirmed, efficient management has been difficult.

For the above reasons, Korean Patent No. 10-1227188 entitled " leveling system for minimizing errors in geodetic survey data " has been proposed.

However, in the above-mentioned Korean Patent No. 10-1227188, " leveling system for minimizing the occurrence of errors in geodetic survey data ", not only has a structure in which a skeleton is erected from the top of the surface- The risk of collapsing due to the external force of the wind or the like is large, and the danger is that due to the reflection mechanism installed at the top of the table chuck Was weighted.

Further, since the reflection mechanism is provided at the upper end of the table chuck, the function of preventing the flywheel approach of the reflection mechanism can not be exerted well.

Korean Registered Patent No. 10-1227188 (Announcement of Mar. 28, 2013), "Level Measurement System to Minimize Error of Geodetic Survey Data" Korean Registered Patent No. 10-1223124 (Announcement on Jan. 17, 2013), "Level Measurement Observation System to Minimize Error Rate of Surface Geodetic Survey"

In the embodiment of the present invention, it is possible to install the skateboard in a state in which an error due to the ground state is prevented, and at the same time, the point where the lower end of the skate chuck is placed can be selectively adjusted in consideration of the length, The inclination of the fixture can be prevented more easily, the scales can be easily wiped so that the scale of the mark can be easily seen, and the geodesic marks, which minimize the measured error value for integrally confirming the plane coordinates and the altitude information, Thereby providing a surveying device.

In addition, the embodiment of the present invention is characterized in that the reflection mechanism for preventing approach of the flywheel to the skeleton does not act as an obstacle to the centering of the skeleton and its fixing mechanism, and at the same time, In the vicinity of the reference point.

In addition, the embodiment of the present invention is characterized in that the fixing mechanism for installing the skate in a state in which an error due to the ground state is prevented is provided with an auxiliary supporting means so as to maximize the support performance and thus the fall- The present invention provides a geodetic surveying apparatus which minimizes an error value.

The geodetic measurement apparatus for minimizing the measured error value according to the embodiment of the present invention has a receiving space 111a formed therein and a top insert hole 111c communicating with the receiving space 111a are formed on the top and bottom surfaces, A hose draw-out hole 111e communicating with the accommodation space 111a is formed on the upper surface and a fixing hole 111d is formed on the side surface and an air inflow hole 111f communicating with the accommodation space 111a is formed A body portion 111 and a body portion 111. The body portion 111 is rotatably installed at a lower portion of the body portion 111 and supports the body portion 111 at a predetermined height from the ground, And a plurality of support portions (113) formed with first insertion holes (113a) corresponding to the rotation axis and second insertion holes (113b) having an angular shape spaced apart along the longitudinal direction; A length adjusting hole 122a which is rotatably coupled to the upper portion of the body 111 of the top-and-bottom fixing mechanism 110 and opens at one side in the longitudinal direction is formed along the longitudinal direction inside the length adjusting hole 122a, A plurality of fastening holes 122b are formed in the longitudinal direction of the swivel base 122 so as to be opened in a direction perpendicular to the longitudinal direction of the swivel base 122, A fastening part 123 formed with a through hole 123b1 corresponding to the fastening hole 111d of the body part 111 on the basis of the rotated state of the fastening part 123, A length adjuster 124a movably inserted in the longitudinal direction of the swivel rod 122a in the longitudinal direction of the swivel arm 122a and a swivel passage hole 124c1 rotatably coupled to one end of the length adjuster 124a in the longitudinal direction, A through-hole passing portion 124c and a through-hole passing portion 124c, Shaped dust removing unit 124d2 which is detachably coupled to the through-hole 124c1 of the dust removal installation hole 124d1 and formed in the dust removal installation hole 124d1 with a dust removal installation hole 124d1 therein, A top dust removing mechanism 120 including a dust removing body 124 including a detachable body 124d to which the dust removing body 124 is coupled; The top dust removing mechanism 120 detachably inserted into the through hole 123b1 of the coupling part 123 and the fixing hole 111d of the body part 111 and including the rotation table 122, A first fastening member 130 for fixing the first fastening member 130 in a state of being fixed; A second fastening member 140 detachably inserted into the length adjusting hole 122a of the swivel arm 122 to fix the length adjustable member 124a; A first pulley 151 installed on both sides of the insert hole 111c in the receiving space 111a of the body 111 and a second pulley 151 disposed on both sides of the insert hole 111c, And a decelerator 152b coupled to a drive shaft of the normal / reverse rotation motor 152a and operatively coupled to the first and second pulleys 151a and 152b to rotate the first and second pulleys 151 and 152, A pulley drive unit 152 installed in the receiving space 111a for each of the first pulleys 151 and a second pulley 151 installed for each of the first pulleys 151 and wound around the first pulley 151, The wire 153 which is unwound from the first pulley 151 or wound around the first pulley 151 according to the rotation direction of the first pulley 151 is larger in size than the size of the upright insertion hole 111c And the first pulleys 151 are disposed on both sides of the first pulleys 151 on the basis of the horizontal direction, A power supply unit 155 installed on the body part 111 for supplying power to the normal and reverse rotation motors 152a, The power supply unit 155 may be installed on the body 111 in such a state that the first manual operation unit 156a is exposed on the outer surface of the body part 111, And a first actuating switch (156) for turning on / off the power supply to the constant-rotation motor (152a) An air compressor 161 installed in an accommodation space 111a of the body part 111 and an air compressor 160 connected to one end in the longitudinal direction of the air compressor 161 to transfer air discharged from the air compressor 161, And a coupling band 162b for tightening the coupling portion 162a is formed at the other end of the air transfer hose 162a formed at a position adjacent to the coupling portion 162a And a hooking ring 163a connected to the air conveying hose 162 and expanded through the air discharged from the air compressor 161 and having a metal reflective layer formed on the outer surface thereof and having elasticity on the outer surface thereof, And the second manual operating portion 164a is installed on the body portion 111 in a state in which the second manual operating portion 164a is exposed to the outer surface of the body portion 111. The operation of the second manual operating portion 164a The air compressor (1) of the power supply unit (155) And a second operation switch (164) for turning on and off the power supply to the first and second electrodes (61, 61); A rotation shaft 171a rotatably inserted into the first insertion hole 113a of the support portion 113 of the top piece fixing mechanism 110 and a rotation shaft 171b coupled to one side of the rotation shaft 171a from the outside of the support portion 113 And a knob 171c formed on one surface of the rotating disc 171b for rotating operation and a knob 171c formed on the other side of the rotating shaft 171a from the inside of the supporting portion 113. [ A second pulley 172 having an angled insertion groove 172a corresponding to the second insertion hole 113b of the support portion 113 on one surface of the support portion 113 facing the inner surface of the support portion 113, A wire 173 which is wound on a second pulley 172 and wound or unwound according to the rotating direction of the second pulley 172 and a second end connected to one end of the wire 173 in the longitudinal direction, A pile (174) having a tip formed therein, and a pile (174) formed inside the support portion (113) in a width direction of the support portion A winding stopper plate 175 having a periphery thereof fixed to the inner surface of the upper support portion 113 and having a wire hole 175a formed in the center thereof for passage of the wire 173, And is inserted into the insertion groove 172a of the second pulley 172 through the second insertion hole 113b of the support portion 113 via the connection cord 176a to the rotary disk 171b, The second insertion hole 113b of the support portion 113 and the insertion groove 172a of the second pulley 172 are formed so that one end of the pile 174 in the longitudinal direction (170) including a fall preventing mechanism (170) formed to be in a state of being opposed to each other in a state in which the rotating operation portion (171) and the second pulley (172) ) Is inserted into the upright insertion hole 111c of the body part 111 and the lower end is inserted into the upright mounting height adjusting mechanism 150, And a scale is formed along the longitudinal direction of the scallop support structure so that the silver foil bubble 163 of the reflection mechanism 160 is supported. (200) on which a support ring (210) for holding a retaining ring (163b) of the retaining ring (163) is inserted is formed on the lower surface of the overhang support plate (155) A distance measuring device 300 for measuring a distance between the upper surface and the lower surface of the base 100; a transmitter 400 installed in the upper surface mounting mechanism 100 for transmitting a distance value measured through the distance measuring device 300; And an input device 510 for confirming the scale of the sculpture 200 and for inputting the confirmed scale. The distance measuring device 300 measures the distance between the scale input from the input device 510 and the distance measured by the distance measuring device 300 And calculates the distance from the ground surface A level unit 500 for calculating the height up to the identified scale; a storage unit 610 for storing elevation information of each point collected through the level unit 500; and an elevation information transmission module 620 for transmitting elevation information And an elevation information collecting unit 600 for receiving the elevation information obtained at a plurality of points from the elevation information transmitting module 620 of the elevation information collector 600. [ (B1), a geodesic survey data DB (B2) for storing elevation information according to the plane coordinates of each point, and a display module (B3) for displaying the plane coordinates and elevation information stored in the geodesic survey data DB And a geodesic survey data collection device (B).

According to the embodiment of the present invention, it is possible to install the skateboard in a state in which an error due to the ground state is prevented, and also to adjust the point at which the bottom of the skate chuck is placed at various heights in consideration of the length, It is possible to prevent the skidding and the fixing mechanism from falling more easily, and to confirm the plane coordinates and the altitude information in an integrated manner.

In addition, the scales can be easily wiped so that the marks on the scale can be seen clearly.

In addition, the reflection mechanism for preventing the access of the flywheel to the skeleton does not act as an obstacle to the centering of the skeleton and its fixing mechanism, and at the same time, the flywheel can be improved.

In addition, the fixing mechanism for mounting the skeleton in a state in which an error due to the ground state is prevented can include the auxiliary supporting means, so that the supporting performance against the ground and thus the fall preventing function can be maximized.

1 is a diagram illustrating a general progress of a leveling survey;
2 is a block diagram illustrating a geodetic survey apparatus for minimizing a measured error value according to an embodiment of the present invention.
3 is a diagram illustrating an elevation measurement apparatus in a geodetic survey apparatus for minimizing a measured error value according to an embodiment of the present invention
Fig. 4 is a view showing a side-by-side mounting mechanism in the elevation measuring apparatus according to Fig. 3
Fig. 5 is a detailed drawing showing the X portion of Fig. 4
Fig. 6 is a view showing the Y portion of Fig. 4 in detail
Fig. 7 is a plan view of the block mounting mechanism according to Fig.
8 is a view showing a reflection mechanism in the elevation measuring apparatus according to Fig. 3
Fig. 9 is a perspective view illustrating the disassembled state of the reflection mechanism of Fig.
Figs. 10 to 15 are diagrams illustrating an example of using the apparatus for measuring altitude according to Fig. 3
16 is a diagram illustrating another embodiment of an altitude measurement apparatus in a geodetic survey apparatus for minimizing a measured error value according to an embodiment of the present invention
Fig. 17 is a view showing a side-by-side mounting mechanism in the elevation measuring apparatus according to Fig. 16
Fig. 18 is a block diagram illustrating the electrical configuration of the block mounting mechanism according to Fig. 17
19 and 20 are views showing an example of use of the sprocket mounting mechanism according to FIG. 17

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components in each described embodiment may be varied without departing from the spirit and scope of the present invention.

The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which the claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term, not on the name of a simple term, but on the entire contents of the present invention.

Whenever an element is referred to as " including " an element throughout the description, it is to be understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. In addition, the term " "... Module " or the like means a unit for processing at least one function or operation, which may be implemented in hardware or software, or a combination of hardware and software.

2 to 20, a geodesic survey apparatus for minimizing a measured error value according to an embodiment of the present invention will be described.

FIG. 2 is a block diagram illustrating a geodetic surveying apparatus for minimizing a measured error value according to an embodiment of the present invention. FIG. 3 is a block diagram of a geodetic surveying apparatus for minimizing a measured error value according to an embodiment of the present invention. 4 is a view illustrating an example of a top mounting mechanism in the elevation measuring apparatus according to FIG. 3, FIG. 5 is a detailed view of an X portion in FIG. 4, and FIG. 6 is a cross- Fig. 7 is a plan view of the sparse installation mechanism according to Fig. 4, Fig. 8 is a view showing a reflection mechanism in the apparatus for measuring altitude according to Fig. 3, and Fig. 9 is a view showing a reflection mechanism according to Fig. Is a perspective view exemplified in a disassembled state.

The geodetic measurement apparatus for minimizing the measured error value according to the present invention includes an altimetry measurement apparatus A and a geodetic survey data collection apparatus B in communication with the altimetry apparatus A. [

The elevation measuring apparatus A includes a table setting mechanism 100, a skid 200, a distance measuring device 300, a transmitter 400, a leveling device 500, an elevation information collecting device 600 and a reflecting device 700 .

The elevation installation mechanism 100 includes a table fixing mechanism 110, a surface dust removing mechanism 120, a first fastening member 130 and a second fastening member 140.

The slide fixture mechanism 110 includes a body portion 111, a locking portion 112, and a support portion 113.

The body part 111 includes a receiving space 111a formed therein and a distance measuring instrument mounting hole 111b disposed below the receiving space 111a and communicating with the receiving space 111a and opening downward, A top insertion hole 111c which is disposed on the upper portion of the side wall 111a and communicates with the accommodation space 111a and opens upward and a fixing hole 111d which is formed to open sideways on the side surface.

The engaging portion 112 is formed at the upper end of the body portion 111 and protrudes upward.

The support portion 113 is rotatably installed at a lower portion of the body portion 111 to support the body portion 111. At this time, a plurality of support portions 113 are provided, and the body portion 111 is stably supported by a tripod structure.

The superficial dust removing mechanism 120 includes a support 121, a swivel 122, a fastening portion 123, and a dust removing member 124.

The support base 121 is disposed on the upper portion of the body portion 111 of the table fixing mechanism 110 and is disposed in front of the engagement portion 112.

The swivel base 122 has a length adjusting hole 122a formed along the longitudinal direction and opened laterally and a plurality of fastening holes 122b communicating with the length adjusting hole 122a and opening upward, And is rotatably installed on the support base 121.

The fastening part 123 includes a protruding part 123a projecting upwardly from the upper end of the rotation table 122 and a fastening part 123b projecting laterally from the protruding part 123a and having a through hole 123b1 opened upward. .

The dust removing member 124 includes a length adjuster 124a that is movably inserted into the length adjusting hole 122a of the rotating table 122 and has one end protruding from the length adjusting hole 122a, A swash plate passing portion 124c provided on an upper portion of the rotating body 124b and having a through hole 124c1 that is open to the side and a rotatable body 124b rotatably installed at one end of the rotating body 124b, A dust removing part 124d2 of cloth material which is detachably installed in the through hole 124c1 of the overhanging part 124c and is formed in the dust removing installation hole 124d1 in the form of a pipe, And a detachable body 124d provided with a detachable body 124d.

The first fastening member 130 is detachably inserted into the through hole 123b1 of the fastening part 123 and the fastening hole 111d of the body part 111 to fix the surface dust removing mechanism 120. [ It is preferable that the first fastening member 130 is threadedly coupled to the through hole 123b1 of the fastening part 123 and the fastening hole 111d of the body part 111. [

The second fastening member 140 is detachably inserted into the length adjusting hole 122a of the swivel base 122 to fix the length adjusting rod 124a. At this time, it is preferable that the second fastening member 140 is threadedly coupled to the length adjusting hole 122a of the swivel base 122. [

The skeleton 200 is detachably inserted into the skeleton insertion hole 111c of the skeletal setting mechanism 100 and a scale is displayed on the circumferential surface.

In the present embodiment, the skeleton 200 is a typical one used for level measurement, and a detailed description thereof will be omitted.

The distance measuring instrument 300 is installed in the distance measuring instrument mounting hole 111b of the table fixing mechanism 110 and measures the distance from the bottom surface of the table 200 to the ground. In the present embodiment, the distance measuring device 300 measures a distance using ultrasonic waves, infrared rays, etc., and a detailed description thereof will be omitted.

The transmitter 400 is installed in the top mount installation mechanism 100 and wirelessly transmits the distance value of the distance measuring device 300.

The level device 500 includes an input device 510 for inputting an identified scale while confirming the scale of the top 200 mounted on the surface mounting mechanism 100, And calculates the distance from the distance measuring device 300 to calculate the height from the ground to the scale of the skate 200.

The leveler 500 can also communicate with the reference station 10 and the satellite G to obtain accurate plane position coordinate values.

The reference station 10 includes a GPS receiver 11 having a GPS antenna 11a and receiving a position value from the satellite G and a GPS receiver 11 for calculating a current position value transmitted from the GPS receiver 11, And a DGPS transmitter 13 that includes a DGPS antenna 13a and receives a GPS correction value from the controller 12 and wirelessly transmits the corrected GPS correction value to the outside.

The GPS correction value (i.e., the position value) calculated through the control unit 12 of the reference station 10 is transmitted to the DGPS transmitter 13 and transmitted through the DGPS antenna 13a connected to the DGPS transmitter 13 Level transmitter 500 as shown in FIG.

The level device 500 includes a DGPS receiver 520 having a DGPS antenna 521 and receiving a GPS correction value from the DGPS transmitter 13 of the reference station 10, a GPS antenna 531, The GPS receiver 530 receives the current position value from the DGPS receiver 520 and the GPS position correction value from the DGPS receiver 520 to determine the precise position of the leveler 500 And a control unit 540 for controlling the control unit 540.

Meanwhile, in the present embodiment, the general function of the level device 500 is well-known technology, and a detailed description thereof will be omitted.

The elevation information collector 600 includes a storage unit 610 for storing elevation information of each point collected using the level device 500 and an elevation information transmission module 620 for transmitting elevation information .

The reflection mechanism 700 includes a fixing mechanism 710, a reflector mounting mechanism 720, and a reflector 730.

The fixing mechanism 710 forms an opening hole 711 and a rotation groove 712.

The opening hole 711 is opened downward and is detachably inserted into the top of the top piece 200. At this time, the opening hole 711 may be provided with a packing mechanism so that the pusher 200 can be easily press-fitted.

The rotation groove 712 is formed in the periphery with an opening hole 712a opened to the outside room and a receiving groove 712b communicating with the opening hole 712a and having a larger width than the opening hole 712a. At this time, a plurality of rotation grooves 712 are provided in the peripheral portion.

The reflector setting mechanism 720 includes a rotation plate 721 rotatably received in the receiving groove 712b of the fixing mechanism 710 and a projection 722a projecting from the rotation plate 721 in a state in which an opening groove 722a opened to the outside is formed. And a rotation bar 722 rotatably disposed in the opening hole 712a of the fixing mechanism 710. [ At this time, the opening groove 722a may be provided with a packing mechanism so that the press-in portion 731 of the reflector 730 can be easily press-fitted. Further, it is preferable that a plurality of reflector installation mechanisms 720 are provided.

The reflector 730 includes a press-in portion 731 which is detachably press-fitted into the opening groove 722a of the reflector setting mechanism 720 and a reflector 732 which is provided on the press-in portion 731 . At this time, the reflective portion 732 is provided with a reflective sheet coated with a reflective material or coated with a reflective material.

The geodetic survey data collection device B includes a reception module B1 for receiving the respective elevation information obtained at a plurality of points from the elevation information transmission module 620 of the elevation information collector 600, And a display module B3 for displaying plane coordinates according to elevation information and elevation information stored in the geodesic survey data DB (B2). At this time, the elevation information includes the plane coordinates according to the elevation information, so that the plane coordinates of the point where the elevation information is obtained can be accurately confirmed. On the other hand, the geodetic survey data collecting device B can be carried by a user in the terminal form or installed in the level device 500.

10 to 15 are views for explaining the use state of the present invention. The use state of the present invention will be described with reference to FIGS. 10 to 15. FIG.

First, as shown in FIG. 10, the table spinal dust removing mechanism 120 is set up, and then the top surface dust removing mechanism 120 is fixed using the first fastening member 130.

At this time, the table spinal cord adjusts the height of the detachable body 124d of the dust removing body 124 while moving the length adjuster 124a of the surface dust removing mechanism 120 up and down, and then uses the second fastening member 140 Thereby fixing the length adjuster 124a as shown in FIG.

Subsequently, the table spinal cord is rotated to a position where it is convenient for the user to insert the removable object 200 into the removable object 124d of the dust removing object 124, and then the object 200 is inserted as shown in FIG.

At this time, the spinal cord moves the headpiece 200 upward or downward. Then, the surface of the surface mount 200 is wiped by the dust removing unit 124d of the dust removing member 124 to remove the dust adhering to the surface.

On the other hand, the removable member 124d of the dust removing member 124 is rotatable, so that the surface of the table 200 can be wiped at various positions where the table spinal water is easy to work as shown in FIG.

Subsequently, the spinal cord pushes the reflection mechanism 700 into the upright 200.

The table spinal cord is adjusted by horizontally aligning the spindle setting mechanism 100 by adjusting the support portion 113 of the spindle fixing mechanism 110, 111c. Thereafter, the number of machines reads the scale of the table 200 by the level machine 500.

14, the distance measured from the bottom of the skid 200 to the ground is measured, and the measured distance is measured by the leveler 500 through the transmitter 400 ).

Then, the leveler 500 obtains the elevation information of the point where the skeleton 200 is installed by adding the scale value inputted by the machine number and the distance value measured by the distance measuring device 300.

Thereafter, the table spinal cord and the number of machines are continuously subjected to a general leveling method to collect elevation information at various points, and elevation information according to the collected elevations is transmitted to the elevation information transmitting module 620 of the elevation information collector 600 To the geodetic survey data collecting device (B).

At this time, the geodetic survey data collecting device B receives the plane position coordinates according to the elevation information and the elevation information through the receiving module B1, and stores the received elevation information in the geodesic survey data DB (B2) do.

On the other hand, when the machine number is read by the scale 200, if the bird or flyer flies around the scale 200, the machine number can not read the scale accurately.

However, in the case of the present invention, the reflector 732 of the reflection mechanism 700 reflects light as shown in FIG. 15 and the birds or the flywheel do not approach the periphery of the skeleton 200, . Particularly, the present invention can maximize the reflection effect while the reflector 730 rotates when the wind is blown.

As described above, according to the present invention, it is possible to precisely measure the level of the algae or the flyweed by preventing the access of the flywheel 200 to the leveling surface 200. When the surface of the flywheel 200 is wiped, The surface can be conveniently and quickly wiped, and the dust on the surface of the skis 200 can be removed, so that the number of machines can be more precisely measured during the leveling work, and the altitude measurement device A, It is possible to integrally collect the plane position coordinates according to the information and the altitude information, thus enabling the integrated management of the geodetic survey data.

Next, another embodiment of the elevation measuring apparatus in the geodetic survey apparatus for minimizing the measured error value according to the embodiment of the present invention will be described with reference to FIGS. 16 to 20. FIG.

16 is a view illustrating another embodiment of the elevation measuring apparatus in the geodetic surveying apparatus for minimizing the measured error value according to the embodiment of the present invention. And FIG. 18 is a block diagram illustrating the electrical configuration of the sprocket mounting mechanism according to FIG.

Prior to the description, the overall configuration and operation of the elevation measuring apparatus A 'according to the present embodiment and the geodetic surveying apparatus for minimizing the measured error value including the same are the same as those of the elevation measuring apparatus A ), And a geodetic surveying apparatus that minimizes the measured error value including it, and there is a difference in a part of the configuration and operation of the altimeter measuring apparatus A '. Therefore, the following description will focus on these differences, The other basic configuration and operation will be understood through the description of the geodetic survey apparatus which minimizes the measured error value described with reference to Figs. 2 to 15. Fig.

As shown in the figure, the elevation measuring apparatus A 'includes a slab installation mechanism 100, a skid 200, a distance measuring device 300, a transmitter 400, a leveler 500, and an altitude information collector 600 Here, the transmitter 400, the leveler 500, and the elevation information collector 600 are the same as those of the elevation measuring apparatus A of the geodetic survey apparatus for minimizing the error value described with reference to Figs. 2 to 15, And will be described with reference to the block mounting mechanism 110, the top block 200, and the distance measuring unit 300. FIG.

The surface mounting mechanism 100 includes a table fixing mechanism 110, a surface dust removing mechanism 120, a first fastening member 130, a second fastening member 140, a vertical mounting height adjusting mechanism 150, 160 and a fall prevention mechanism 170. [

The slide lock mechanism 110 includes a body portion 111 and a plurality of support portions 113. [

The body part 111 has a receiving space 111a formed therein and a top insert hole 111c communicating with the receiving space 111a is formed on the upper and lower surfaces respectively and a hose draw- A hole 111e is formed. The body portion 111 has a fixing hole 111d formed on a side surface thereof and an air inlet hole 111f communicating with the accommodation space 111a.

The plurality of support portions 113 are rotatably installed at a lower portion of the body portion 111. The support portions 113 function to support the body portion 111 at a predetermined height from the ground. Each of the support portions 113 has a hollow shape with its lower portion opened and a first insertion hole 113a and an angled second insertion hole 113b corresponding to a circular rotation axis are formed on the upper portion so as to be spaced apart along the longitudinal direction .

The superficial dust removing mechanism 120 includes a rotating table 122, a fastening portion 123, and a dust removing body 124.

The rotation table 122 is rotatably coupled to the upper portion of the body portion 111 of the table fixing mechanism 110 and has a length adjusting hole 122a opened at one side in the longitudinal direction thereof along the longitudinal direction, A plurality of fastening holes 122b communicating with the holes 122a and opened in a direction perpendicular to the longitudinal direction are formed along the longitudinal direction.

The fastening part 123 is formed at one end in the longitudinal direction of the rotating table 122 and is rotated in conjunction with rotation of the rotating table 122. The fastening part 123 is formed with a through hole (123b1) are formed.

The dust removing member 124 includes a length adjuster 124a which is inserted into the length adjusting hole 122a of the rotating table 122 so as to be movable along the longitudinal direction of the rotating table 122, A swash plate passing portion 124c which is rotatably coupled at one end and through which the swash plate passing hole 124c1 is passed and a swash plate passing hole 124c1 of the swash plate passing portion 124c, And a removable body 124d having a dust removing portion 124d1 formed therein and a pipe-shaped dust removing portion 124d2 formed of a cloth material to be coupled to the dust removing installation hole 124d1.

The first fastening member 130 is detachably inserted into the through hole 123b1 of the fastening part 123 and the fastening hole 111d of the body part 111 and is provided with a surface dust removing mechanism 120 Is fixed in a rotated state.

The second fastening member 140 is detachably inserted into the length adjusting hole 122a of the rotating table 122 to fix the length adjusting rod 124a.

2 to 15, as described above, the more detailed configuration and operation of the top-and-bottom fixing mechanism 110, the top-surface dust removing mechanism 120, the first fastening member 130 and the second fastening member 140 Reference will be made to the corresponding configurations of the elevation measuring apparatus A described with reference to FIG.

The slat mounting height adjustment mechanism 150 includes a first pulley 151, a pulley drive unit 152, a wire 153, a swiveling support plate 154, a power supply unit 155 and a first operation switch 156 .

The first pulleys 151 are installed on both sides of the insertion hole 111c in the receiving space 111a of the body part 111, respectively.

The pulley drive unit 152 includes a forward and reverse rotation motor 152a that generates power for rotating the first pulley 151 and a drive shaft of the forward and reverse rotation motors 152a, And a speed reducer 152b that transmits rotational power to the first pulley 151. [ The pulley drive unit 152 is mounted on the pulley 151 in the receiving space 111a of the body unit 111. [

The wire 153 is provided for each of the first pulleys 151. The wire 153 is wound around the first pulley 151 and is pulled out from the first pulley 151 in accordance with the rotation direction of the first pulley 151, (151).

The upper surface of the upper support plate 154 is formed to have a larger area than the size of the upright insertion hole 111c and a wire 153 ).

The power supply unit 155 is installed in the body part 111 to supply power to the normal rotation motor 152a.

The first operation switch 156 is installed on the body 111 in such a state that the first manual operation portion 156a is exposed to the outer surface of the body portion 111. The first operation switch 156 is connected to the first manual operation portion 156, The power supply to the normal and reverse rotation motors 152a of the power supply unit 155 is turned on and off according to the operation state of the motor 156a.

The position of the upright 200 to be erected with the center of the upright insertion hole 111c of the body part 111 as a center is raised by the above-mentioned upright mounting height adjusting mechanism 150, The height of the point where the scoop 200 is raised is reduced as the length of the scoop 200 is increased and the load of the scoop 200 and the scoop fixing mechanism 110 is further lowered, It is possible to suppress the occurrence of the overturning of the heat sink 110 as much as possible.

The reflection mechanism 160 is configured to include an air compressor 161, an air transfer hose 162, a silver balloon 163, and a second operation switch 164.

The air compressor (161) is installed in the receiving space (111a) of the body part (111).

The air transfer hose 162 is connected to the air compressor 161 at one end in the longitudinal direction to transfer air discharged from the air compressor 161 and has a reduced diameter portion 162a formed at the other end in the longitudinal direction At the same time, a binding band 162b for tightening the binding portion 162a is formed at a position adjacent to the binding portion 162a.

The silver foil balloon 163 is connected to the air conveying hose 162 and expanded through the air discharged from the air compressor 161. The metal foil reflection layer is formed on the outer surface of the silver foil balloon 163. The retaining ring 163a, .

The second operation switch 164 is installed on the body 111 in such a state that the second manual operation portion 164a is exposed on the outer surface of the body portion 111. The second operation switch 164 is provided on the second manual operation portion 164a, Off of the power supply to the air compressor 161 of the power supply unit 155 according to the operation state of the air compressor 161. [

Most of the structures for forming the reflection mechanism 160 such as the air compressor 161 and the air transfer hose 162 are supported by the body of the body part 111, The reflective mechanism 160 does not act as an obstacle to the centering of the top 200 and the top mount fixing mechanism 110 because only the silver balloon 163 is coupled and supported on the base 200. Since the reflection mechanism 160 is integrally provided in the table fixing mechanism 110, it is possible to fundamentally prevent the difficulty of misunderstanding due to the loss or mistake of the reflection mechanism generated in the conventional independent reflection mechanism. In addition, since the reflecting portion 160 is formed of the silver foil balloon 163 serving as an actual insect fighting function, the insect fighting function can be greatly improved.

19 is a diagram illustrating the use state of the reflection mechanism. The operator operates the second operation switch 164 to fill the silver foil balloon 163 with air and bind the binding portion 162a of the air transfer hose 162 The silver balloon 163 filled with the air is hooked on the support hook 210 of the skeleton 200 through the hook ring 163b so that air can not escape from the silver foil balloon 163 while being bound to the band 162b .

Referring back to Figs. 16 to 18, the fall preventing mechanism 170 includes a rotation operating portion 171, a second pulley 172, a wire 173, a pile 174, a winding stop plate 175, 176).

The rotary operation portion 171 is provided with a rotary shaft 171a which is rotatably inserted into the first insertion hole 113a of the support portion 113 of the top piece fixing mechanism 110 and a rotary shaft 171b which is provided on one side of the rotary shaft 171a from the outside of the support portion 113 And a knob 171c formed on one surface of the rotating disc 171b for rotating operation.

The second pulley 172 is coupled to the other side of the rotary shaft 171a on the inner side of the support portion 113 and on the side opposite to the inner side of the support portion 113 is connected to the second insertion hole 113b of the support portion 113 An angled insertion groove 172a is formed.

The wire 173 is wound around the second pulley 172 and wound or unwound along the direction of rotation of the second pulley 172. [

One end of the pile 174 in the longitudinal direction is connected to one end of the wire 173, and the other end in the longitudinal direction forms a peak.

The winding support plate 175 is disposed inside the support portion 113 in the width direction of the support portion 113 and its periphery is fixed to the inner surface of the support portion 113 and has a wire hole 175a are formed.

The rotation preventing rod 176 is coupled to the rotating circular plate 171b of the rotation operating part 171 through a connecting cord 176a and is inserted into the second insertion hole 113b of the supporting part 113, And is inserted into the insertion groove 172a.

The second insertion hole 113b of the support portion 113 and the insertion groove 172a of the second pulley 172 are inserted into the rotation operating portion 171 until the one end in the lengthwise direction of the pile 174 contacts the take- And the pulley 172 are in the advanced state.

When the top piece 200 and the top piece mounting mechanism 100 are used in a terrain type such as a mountain or a hill by the above-described fall preventing mechanism 170, the top piece fixing mechanism 110 of the top piece mounting mechanism 100 can be prevented from falling 170 and can be prevented from being tilted by the top and bottom lock mechanisms 110 and 110. In addition, Such a function can be exerted more effectively when the skid 200 and the scarf installation mechanism 100 are installed on an inclined terrain.

20 is a diagram illustrating the use state of the fall preventing mechanism 170. The operator inserts the rotation preventing rod 176 into the insertion groove 172a of the second pulley 172 and the second insertion hole The pile 174 and the wire 173 support the supporting part 113 by fixing the pile 174 drawn out from the supporting part 113 to a predetermined point on the ground It is possible to prevent the slip-and-lock mechanism 110 from falling over.

16 to 18, the skeleton 200 is inserted into the skeletal insertion hole 111c of the body part 111 and the lower end thereof is mounted on the skeletal support plate 155 of the skeletal installation height adjusting mechanism 150, And is installed upright on the mounting mechanism 100. The support 200 has a support ring 210 in which a scale is displayed along the longitudinal direction and the retaining ring 163b of the silver foil balloon 163 is inserted and supported so as to support the silver ore balloon 163 of the reflection mechanism 160 .

The distance measuring device 300 is installed on the lower surface of the block supporting plate 155 of the block mounting height adjusting mechanism 150 and measures the distance to the ground.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all the equivalents or equivalents of the claims, as well as the claims set forth below, fall within the scope of the present invention.

B3: Display module 100:
110: a rack fixing mechanism 111:
112: fastening part 113:
120: superficial dust removing mechanism 122: turntable
123: fastening part 124: dust removing body
130: first fastening member 140: second fastening member
150: Height adjustment mechanism for the vertical installation 151: First pulley
152: pulley drive unit 153: wire
154: Spacer support plate 155: Power supply unit
156: first operation switch 160: reflection mechanism
161: Air compressor 162: Air conveying hose
163: silver balloon 164: second operation switch
170: a fall preventing mechanism 171:
172: second pulley 173: wire
174: Pile 175: Retraction stop plate
176:

Claims (1)

And a hose draw-out hole 111e communicating with the receiving space 111a is formed on the upper surface of the hood draw-out hole 111e, A body portion 111 having a side surface formed with a fixing hole 111d and an air inlet hole 111f communicating with the receiving space 111a; And the body portion 111 is supported at a predetermined height from the ground. Each of the first and second insertion holes 113a and 113b has a hollow shape with an opened lower portion and a first insertion hole 113a corresponding to a circular rotation axis, (111) including a plurality of supports (113) formed such that the holes (113b) are spaced along the longitudinal direction;
A length adjusting hole 122a which is rotatably coupled to the upper portion of the body 111 of the top-and-bottom fixing mechanism 110 and opens at one side in the longitudinal direction is formed along the longitudinal direction inside the length adjusting hole 122a, A plurality of fastening holes 122b are formed in the longitudinal direction of the swivel base 122 so as to be opened in a direction perpendicular to the longitudinal direction of the swivel base 122, A fastening part 123 formed with a through hole 123b1 corresponding to the fastening hole 111d of the body part 111 on the basis of the rotated state of the fastening part 123, A length adjuster 124a movably inserted in the longitudinal direction of the swivel rod 122a in the longitudinal direction of the swivel arm 122a and a swivel passage hole 124c1 rotatably coupled to one end of the length adjuster 124a in the longitudinal direction, A through-hole passing portion 124c and a through-hole passing portion 124c, Shaped dust removing unit 124d2 which is detachably coupled to the through-hole 124c1 of the dust removal installation hole 124d1 and formed in the dust removal installation hole 124d1 with a dust removal installation hole 124d1 therein, A top dust removing mechanism 120 including a dust removing body 124 including a detachable body 124d to which the dust removing body 124 is coupled;
The top dust removing mechanism 120 detachably inserted into the through hole 123b1 of the coupling part 123 and the fixing hole 111d of the body part 111 and including the rotation table 122, A first fastening member (130) for fastening the first fastening member
A second fastening member 140 detachably inserted into the length adjusting hole 122a of the swivel base 122 to fix the length adjuster 124a;
A first pulley 151 installed on both sides of the insert hole 111c in the receiving space 111a of the body 111 and a second pulley 151 disposed on both sides of the insert hole 111c, And a decelerator 152b coupled to a drive shaft of the normal / reverse rotation motor 152a and operatively coupled to the first and second pulleys 151a and 152b to rotate the first and second pulleys 151 and 152, A pulley drive unit 152 installed in the receiving space 111a for each of the first pulleys 151 and a second pulley 151 installed for each of the first pulleys 151 and wound around the first pulley 151, The wire 153 which is unwound from the first pulley 151 or wound around the first pulley 151 according to the rotation direction of the first pulley 151 is larger in size than the size of the upright insertion hole 111c And the first pulleys 151 are disposed on both sides of the first pulleys 151 on the basis of the horizontal direction, A power supply unit 155 installed on the body part 111 for supplying power to the normal and reverse rotation motors 152a, The power supply unit 155 may be installed on the body 111 in such a state that the first manual operation unit 156a is exposed on the outer surface of the body part 111, And a first operation switch (156) for turning on / off the power supply to the constant-and-reverse rotation motors (152a) of the motor (152a).
An air compressor 161 installed in an accommodation space 111a of the body part 111 and an air compressor 160 connected to one end in the longitudinal direction of the air compressor 161 to transfer air discharged from the air compressor 161, And a coupling band 162b for tightening the coupling portion 162a is formed at the other end of the air transfer hose 162a formed at a position adjacent to the coupling portion 162a And a hooking ring 163a connected to the air conveying hose 162 and expanded through the air discharged from the air compressor 161 and having a metal reflective layer formed on the outer surface thereof and having elasticity on the outer surface thereof, And the second manual operating portion 164a is installed on the body portion 111 in a state in which the second manual operating portion 164a is exposed to the outer surface of the body portion 111. The operation of the second manual operating portion 164a The air compressor (1) of the power supply unit (155) And a second actuation switch (164) for turning on and off the power supply to the first power supply (61);
A rotation shaft 171a rotatably inserted into the first insertion hole 113a of the support portion 113 of the top piece fixing mechanism 110 and a rotation shaft 171b coupled to one side of the rotation shaft 171a from the outside of the support portion 113 And a knob 171c formed on one surface of the rotating disc 171b for rotating operation and a knob 171c formed on the other side of the rotating shaft 171a from the inside of the supporting portion 113. [ A second pulley 172 having an angled insertion groove 172a corresponding to the second insertion hole 113b of the support portion 113 on one surface of the support portion 113 facing the inner surface of the support portion 113, A wire 173 which is wound on a second pulley 172 and wound or unwound according to the rotating direction of the second pulley 172 and a second end connected to one end of the wire 173 in the longitudinal direction, A pile (174) having a tip formed therein, and a pile (174) formed inside the support portion (113) in a width direction of the support portion A winding stopper plate 175 having a periphery thereof fixed to the inner surface of the upper support portion 113 and having a wire hole 175a formed in the center thereof for passage of the wire 173, And is inserted into the insertion groove 172a of the second pulley 172 through the second insertion hole 113b of the support portion 113 via the connection cord 176a to the rotary disk 171b, The second insertion hole 113b of the support portion 113 and the insertion groove 172a of the second pulley 172 are formed so that one end of the pile 174 in the longitudinal direction (170) including a fall preventing mechanism (170) formed to be in a state of being opposed to each other in a state in which the rotating operation portion (171) and the second pulley (172) ):
Is inserted into the upright insertion hole 111c of the body part 111 and installed at the lower end thereof on the upright mounting mechanism 100 while being mounted on the upright supporting plate 154 of the upright mounting height adjusting mechanism 150 And a support ring 210 on which a retaining ring 163b of the silver foil balloon 163 is inserted and supported so as to support the silver foil balloon 163 of the reflection mechanism 160, (200):
A distance measuring device 300 installed on a lower surface of the upright support plate 154 of the upright mounting height adjusting mechanism 150 for measuring a distance to the ground;
A transmitter 400 provided in the sparse installation mechanism 100 for transmitting a distance value measured through the distance measuring device 300;
And an input device 510 for confirming a scale of the skid 200 installed in the scouring mechanism 100 and inputting an identified scale. The scales inputted from the input device 510, (500) for calculating a distance from the ground to an identified scale of the skewer (200) by calculating a distance value measured through the scale (300)
An altitude information collector 600 including a storage unit 610 for storing elevation information of each point collected through the level unit 500 and an elevation information transmission module 620 for transmitting elevation information, The devices (A '),
A reception module B1 for receiving the elevation information obtained from a plurality of points from the elevation information transmission module 620 of the elevation information collector 600 and a geodetic survey data DB for storing elevation information according to the plane coordinates of the respective points B2) and a display module (B3) for displaying plane coordinates and elevation information stored in the geodesic survey data DB (B2). The geodetic surveying data collecting device (B) .

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