CN113063397B - Tunnel cave wall joint structural plane attitude measuring method - Google Patents
Tunnel cave wall joint structural plane attitude measuring method Download PDFInfo
- Publication number
- CN113063397B CN113063397B CN202110318613.XA CN202110318613A CN113063397B CN 113063397 B CN113063397 B CN 113063397B CN 202110318613 A CN202110318613 A CN 202110318613A CN 113063397 B CN113063397 B CN 113063397B
- Authority
- CN
- China
- Prior art keywords
- angle
- measuring
- measured
- tunnel
- horizontal
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Classifications
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C1/00—Measuring angles
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C9/00—Measuring inclination, e.g. by clinometers, by levels
Landscapes
- Physics & Mathematics (AREA)
- Engineering & Computer Science (AREA)
- General Physics & Mathematics (AREA)
- Radar, Positioning & Navigation (AREA)
- Remote Sensing (AREA)
- Geophysics And Detection Of Objects (AREA)
Abstract
The invention relates to the technical field of geotechnical testing, in particular to a tunnel cave wall joint structure surface attitude measurement method, which comprises the following measurement steps: establishing an orthogonal coordinate system by taking the position of a measuring station as an origin O, taking an azimuth angle of 0 degrees as the positive direction of a y axis, taking an azimuth angle of 90 degrees as the positive direction of an x axis and taking the vertical direction as the positive direction of a z axis; measuring a horizontal angle, an azimuth angle and an inclination angle of the tunneling direction of the tunnel; selecting at least three feature points which are not on the same straight line on the structural surface trace, and respectively measuring the distance from the origin O to each feature point and the horizontal angle, the azimuth angle and the inclination angle of the connecting line of the origin and each feature point; and step four, calculating the horizontal angle, the azimuth angle, the inclination angle and the distance of any three points measured in the step three to obtain the attitude information of the structural plane. When the method is used for measuring the tunnel bending section, the coordinate system does not need to be reestablished again, and the measurement calculation can be directly carried out.
Description
Technical Field
The invention relates to the technical field of rock-soil mechanical testing, in particular to a tunnel cave wall joint structure surface attitude measurement method.
Background
The method for carrying out sketch and structural plane statistics on the geological phenomena exposed on the tunnel wall in the tunneling process is an important method for researching and judging the surrounding rock condition of the tunnel, and is a main means for knowing the tunnel geology, the surrounding rock and the stress condition. The traditional sketch usually records the joint quantity and carries out occurrence measurement on a structural surface through manual work, the joint surface is usually extended in a curve form on the tunnel wall after tunnel excavation, a planar structure for direct measurement is not available, therefore, the occurrence of the joint surface or the structural surface is measured in a tunnel, the space position of the joint surface or the structural surface is judged only through a joint trace line or a structural surface trace line extended on the tunnel wall, and the space characteristic of the structural surface is measured through a compass.
The traditional measuring means is mainly that the compass is handed to artifical and is measured on the spot, and is inefficient, and the amount of labour is big, receives the place environment influence great, measures the risk when face country rock condition is poor moreover too high. In other methods adopting total station measurement, a coordinate system which takes the tunnel axial direction as an x axis, the transverse direction as a y axis and the vertical direction as a z axis is established, and calculation and derivation are carried out by utilizing a direction angle, a direction cosine and a trigonometric function according to coordinates of milepost numbers, measuring stations and measuring points to obtain the inclination and the dip angle of the structural surface. The method is too complex in actual operation, and particularly when the curved section of the tunnel is measured, the method is often required to be readjusted to establish a new coordinate system, which is not beneficial to rapidly mapping the occurrence of the structural plane.
Disclosure of Invention
In order to overcome the defects of the prior art, the invention provides the tunnel wall joint structural plane attitude measuring method, which can directly carry out measurement calculation without reestablishing a coordinate system again when measuring the tunnel bending section.
The technical scheme adopted by the invention for solving the technical problems is as follows:
a tunnel cave wall joint structural plane attitude measuring method comprises the following measuring steps:
establishing an orthogonal coordinate system by taking the position of a measuring station as an original point O, taking an azimuth angle of 0 degrees as the positive direction of a y axis, taking an azimuth angle of 90 degrees as the positive direction of an x axis and taking the vertical direction as the positive direction of a z axis;
measuring a horizontal angle, an azimuth angle and an inclination angle of the tunneling direction of the tunnel;
selecting at least three feature points which are not on the same straight line on the structural surface trace, and respectively measuring the distance from the origin O to each feature point and the horizontal angle, the azimuth angle and the inclination angle of the connecting line of the origin and each feature point;
and step four, calculating the horizontal angle, the azimuth angle, the inclination angle and the distance of any three characteristic points measured in the step three to obtain the attitude information of the structural plane.
Under the condition that the geomagnetic field is not interfered, the calculation processing process of the fourth step is as follows:
setting the selected three characteristic points as P 1 、P 2 、P 3 ;
From the origin O to the point P 1 A distance of (a), the origin O and the point P 1 Connected straight line OP of 1 Has a horizontal angle of alpha 1 Azimuthal angle of beta 1 The angle of inclination being gamma 1 ;
From the origin O to the point P 2 A distance of b, the origin O and the point P 2 Connected straight line OP of 2 Has a horizontal angle of alpha 2 Azimuthal angle of beta 2 The angle of inclination being gamma 2 ;
From the origin O to the point P 3 C, the origin O and the point P 3 Connected straight line OP of 3 Has a horizontal angle of alpha 3 Azimuthal angle of beta 3 The angle of inclination being gamma 3 ;
A three-point structural surface equation is thus obtained:
the structural surface equation is obtained by arrangement and is A (x-x) 1 )+B(y-y 1 )+C(z-z 1 )=0
Then the structural plane normal vector N = (a, B, C);
wherein the content of the first and second substances,
the structural surface inclination angle phi is calculated as follows:
an acute angle is formed between the structural plane and the xOy plane, and an xOy plane normal vector Z = (0,0,1) is taken;
-structural plane inclination phi = arccos (| N-Z |/| N | Z |);
the structural plane tendency g is calculated as follows:
taking a normal vector n of the structural surface,
n projection on xOy plane n' = (A, B, 0)
Taking the positive Y-axis vector Y = (0,1,0)
ω=arccos(n’·Y/∣n’∣·∣Y∣)
Tendency of structural surface g
The trajectory line equation of the structure extending towards the heading direction is as follows:
{A(x-x 1 )+B(y-y 1 )+C(z-z 1 )=0
(y-e 1 ) 2 +(z-e 2 ) 2 =r 2
wherein e is 1 E is the horizontal distance between the survey station position and the central axis of the tunnel or the horizontal distance between the survey station position and the central point of the circular arc profile of the tunnel when the survey station is at the left side of the central axis 1 Taking the positive value, when the survey station is at the right side of the central axis e 1 Take a negative value, e 2 Is the vertical distance from the measuring station position to the center point of the tunnel arc profile, e when the measuring station is below the central axis 2 Taking the positive value, when the survey station is above the central axis e 2 Taking a negative value.
Under the condition that the local magnetic field is interfered by a magnetic stratum, the azimuth angle influenced and measured by the magnetic field of the surrounding rock needs to be corrected through the tunneling direction, the tunneling azimuth angle is set to be theta, the tunneling azimuth angle influenced and measured by the magnetic surrounding rock is set to be theta ', delta = theta-theta', wherein delta is the declination angle of the local area, and can be obtained through inquiring topographic map data of the local area, and the calculation processing process of the fourth step is as follows:
let the three selected feature points be P respectively 1 、P 2 、P 3 ;
From the origin O to the point P 1 、P 2 、P 3 The distances of (a) to (c) are respectively a, b and c;
straight line OP 1 The uncorrected azimuth angle measured by the compass is beta 1 ', straight line OP 2 The uncorrected azimuth angle measured by compass is beta 2 ', straight line OP 3 The uncorrected azimuth angle measured by the compass is beta 3 ’;
Straight line OP 1 Is at an inclination angle of gamma 1 Straight line OP 2 Is at an inclination angle of gamma 2 Straight line OP 3 Is at an inclination angle of gamma 3 ;
From this, the structural surface equation can be obtained:
the structural surface equation is obtained by arrangement and is A (x-x) 1 )+B(y-y 1 )+C(z-z 1 )=0
Then the structural plane normal vector: n = (A, B, C) wherein
|bcosγ 2 ·cos(β 2 ’+δ)-acosγ 1 ·cos(β 1 ’+δ) bsinγ 2 -asinγ 1 |
A=|ccosγ 3 ·cos(β 3 ’+δ)-acosγ 1 ·cos(β 1 ’+δ) csinγ 3 -asinγ 1 |
The structural surface inclination angle phi is calculated as follows:
an acute angle is formed between the structural plane and the xOy plane, and an xOy plane normal vector Z = (0,0,1) is taken;
the inclination of the structure plane phi = arccos (| N · Z |/| N | -) Z |;
structural plane tendency calculation g is as follows:
taking a normal vector n of the structural surface,
n projection on xOy plane n' = (A, B, 0)
Taking the positive Y-axis vector Y = (0,1,0)
ω=arccos(n’·Y/∣n’∣·∣Y∣)
Structural plane tendency g
The trajectory line equation of the structure extending towards the tunneling direction is as follows:
wherein e is 1 The horizontal distance between the measuring station position and the central axis of the tunnel or the horizontal distance between the measuring station position and the central point of the circular arc profile of the tunnel is measured, and the measuring station position is on the left side of the central axis e 1 Taking a positive value, when the measuring station is positioned at the right side of the central axis e 1 Take a negative value, e 2 Is the vertical distance from the measuring station position to the center point of the tunnel arc profile, e when the measuring station position is below the central axis 2 Taking a positive value, when the measuring station is above the central axis e 2 Taking a negative value.
Wherein, before step one, place the tripod earlier, then install the measuring apparatu on the tripod, adjust tripod and measuring apparatu after that, make the bubble of the circular level ware of measuring apparatu and long level ware central, the measuring apparatu is in the horizontality.
In the second step, before measurement, a telescope of the measuring instrument is adjusted to enable the central axes of the eyepiece and the objective to be horizontal, the eyepiece points to the tunneling direction, at the moment, the horizontal angle, the azimuth angle and the inclination angle of the tunneling direction are measured, and the measuring instrument reads and records data after measurement.
In the third step, during measurement, a coarse collimation device of the measuring instrument is firstly used for aligning a target to carry out coarse collimation, then a telescope of the measuring instrument is adjusted to align with the feature points on the exposed structural plane trace in the effective measuring distance range, after the reading is stable, the horizontal angle degree, the azimuth angle degree, the inclination angle degree and the distance between the horizontal angle degree, the azimuth angle degree, the inclination angle degree and the measuring station position of the feature points are read and recorded, the steps are repeated, the horizontal angle, the azimuth angle, the inclination angle and the distance between the horizontal angle degree, the azimuth angle, the inclination angle degree and the measuring station position of at least three feature points are measured, and finally the measured data are input into a computing system to obtain a structural plane equation and structural plane occurrence information.
In the fourth step, if the difference between the measured horizontal angle degree of the characteristic point and the measured horizontal angle degree of the tunneling direction is equal to the difference between the measured azimuth angle degree of the characteristic point and the measured azimuth angle degree of the tunneling direction during measurement, the magnetic field of surrounding rocks around the position of the measuring station is stable, and when the computing system computes and processes data, the computing system performs computing processing under the condition of no magnetic field interference;
if an error exists between the difference value of the measured horizontal angle degree of the characteristic point and the measured horizontal angle degree of the tunneling direction and the difference value of the measured azimuth angle degree of the characteristic point and the measured azimuth angle degree of the tunneling direction, the surrounding rock magnetic field around the position of the measuring station is not stable, and when the computing system computes and processes data, the computing system performs computing processing by adopting the condition that the geomagnetic field is interfered by the magnetic stratum.
When measuring the track equation of the structure extending towards the tunneling direction, firstly measuring the vertical distance e between the measuring instrument and the central axis of the tunnel 2 That is, the vertical distance from the position of the survey station to the central axis of the tunnel is e 2 Then measuring the horizontal distance e between the position of the measuring station and the central axis of the tunnel 1 When in measurement, the horizontal distances m and n (m) from the position of the measuring station to the tunnel walls on the two sides of the tunnel are measured>n) to find e 1 = m-n/2, the measured data is input into a computing system for computing processing, and a track equation of the structure extending towards the tunneling direction can be obtained。
The invention has the beneficial effects that:
the invention provides a method for establishing an orthogonal coordinate system by taking a station position as an origin O, taking an azimuth angle of 0 degrees (a positive north direction N) as a positive y-axis direction, taking an azimuth angle of 90 degrees (a positive east direction E) as a positive x-axis direction and taking a vertical direction as a positive z-axis direction. The method comprises the steps of measuring the distance, the azimuth angle, the inclination angle and the horizontal angle from a characteristic point on a structural surface to a measuring station, solving a plane equation by a three-point method, further solving the inclination and the inclination angle of the structural surface, and obtaining the exposed track equation of the structural surface by the simultaneous establishment of the plane equation and a tunnel profile equation.
The method can be used for directly measuring and calculating without re-establishing a coordinate system under the general condition. And effective correction measures are also provided for the situation that the local magnetic field is disturbed by the magnetic stratum. In addition, the method can be used for checking and supplementing azimuth measurement by measuring the horizontal angle, and the accuracy of the measurement result is effectively ensured.
The method can finish the measurement work without inputting the coordinates of the measuring station under the general condition, if the accurate position coordinates of the measuring station, the measuring points and the structural surface need to be recorded, the marking can be made at the position where the measuring station is established, the point location coordinates of the marking position can be measured by selecting a machine at the later stage, and the coordinates of each measuring point can be obtained through calculation. Effectively reducing the cross operation time and improving the working efficiency. The method is fast and convenient, and can carry out measurement without inputting coordinates of a measuring station, namely, the measurement is carried out immediately, so that the method is fast and convenient.
Drawings
The invention is further illustrated with reference to the following figures and examples.
FIG. 1 is a schematic diagram of establishing a coordinate system according to the present invention.
Detailed Description
The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and those skilled in the art can obtain other embodiments without inventive effort based on the embodiments of the present invention, and all embodiments are within the protection scope of the present invention. In addition, all the connection/connection relations referred to in the patent do not mean that the components are directly connected, but mean that a better connection structure can be formed by adding or reducing connection auxiliary components according to specific implementation conditions. All technical characteristics in the invention can be interactively combined on the premise of not conflicting with each other.
Examples
A tunnel cave wall joint structural plane attitude measuring method comprises the following measuring steps:
firstly, selecting a relatively flat field to place a tripod, then connecting and installing a measuring instrument on the tripod through a bolt, then adjusting the tripod and the measuring instrument to center bubbles of a circular level and a long level of the measuring instrument, and enabling the measuring instrument to be in a horizontal state, as shown in figure 1, taking the measuring position of the measuring instrument as an original point O, taking an azimuth angle of 0 degree (namely a positive north direction) as a y-axis positive direction, taking an azimuth angle of 90 degrees (namely a positive east direction) as an x-axis positive direction, and taking a vertical upward direction as a z-axis positive direction to establish an orthogonal coordinate system;
step two, adjusting a telescope of the measuring instrument to enable the central axes of the ocular and the objective to be in a horizontal state, enabling the ocular to point to the tunneling direction, and measuring the horizontal angle alpha of the tunneling direction at the moment 0 =0 ° azimuth angle β 0 And an inclination angle gamma 0 =0 °, the measuring instrument reads and records the data after measurement;
step three, randomly selecting at least three feature points which are not on the same straight line on the structural surface trace, and respectively measuring the distance from the origin O to each feature point and the horizontal angle, the azimuth angle and the inclination angle of the connecting line of the origin and each feature point, wherein the specific measurement steps are as follows:
firstly, a coarse aiming device of the measuring instrument is used for aligning a target for coarse aiming, at the moment, if the field light is dark, a highlight flashlight can be turned on for illuminating and indicating the target, and then a telescope of the measuring instrument is adjusted to align a characteristic point P on a trace of an exposed structural surface in an effective measuring distance range 1 Locking vertical disc brake hand wheel and base locking button, waiting to readReading and recording the horizontal angle degree alpha of the characteristic point after stabilization 1 Azimuthal angle degree beta 1 Inclination angle degree gamma 1 And the distance a between the measuring station and the measuring station position, repeating the steps, measuring the horizontal angle, the azimuth angle, the inclination angle and the distance between the measuring station position and at least three characteristic points which are not on the same straight line, and finally inputting the measured data into a computing system to obtain a structural plane equation and structural plane occurrence information;
step four, calculating and processing the horizontal angle, the azimuth angle, the inclination angle and the distance of any three characteristic points measured in the step three to obtain the attitude information of the structural plane;
specifically, during measurement, if the horizontal angle degree alpha of the characteristic point is obtained through measurement 1 And the measured horizontal angle degree alpha of the tunneling direction of the tunnel 0 The difference is equal to the azimuth angle degree beta of the measured characteristic points 1 And the measured azimuth angle degree beta of the tunneling direction of the tunnel 0 The difference of, i.e. alpha 1 -α 0 =β 1 -β 0 When the data is calculated and processed by the calculation system, the calculation processing is carried out by adopting the condition without magnetic field interference;
if the measured horizontal angle degree alpha of the characteristic point is obtained 1 And the measured horizontal angle degree alpha of the tunneling direction of the tunnel 0 And the measured azimuth angle degree beta of the characteristic point 1 The azimuth angle degree beta of the tunneling direction obtained by measurement 0 If a large error exists between the difference values, the magnetic field of surrounding rocks around the position of the survey station is unstable, and when the computing system computes and processes data, the computing system performs computing processing by adopting the condition that the geomagnetic field is interfered by the magnetic stratum.
When measuring the track equation of the structure extending towards the tunneling direction, firstly measuring the vertical distance e between the measuring instrument and the central axis of the tunnel 2 That is, the vertical distance from the position of the survey station to the central axis of the tunnel is e 2 Then measuring the horizontal distance e between the position of the measuring station and the central axis of the tunnel 1 During measurement, the horizontal distances m and n (m) from the position of the measuring station to the tunnel walls on the two sides of the tunnel are measured>n) to find e 1 And (m-n)/2, inputting the measured data into a computing system for computing to obtain a track equation of the structure extending towards the tunneling direction.
Specifically, when measuring horizontal distance m and n from the survey station position to the tunnel both sides hole wall, keep the telescope axis inclination degree to be 0, then the horizontal rotation telescope reads the horizontal distance from the survey station position to the tunnel both sides hole wall when the pivoted horizontal angle degree is 90 earlier, read the horizontal distance from the survey station position to the tunnel both sides hole wall when the pivoted horizontal angle degree is 270 again, through measuring the horizontal distance from the survey station position to the tunnel both sides wall when different horizontal angle degrees, twice measurement is favorable to improving measurement accuracy, reduce measuring error.
Wherein, under the condition that the local magnetic field is not interfered, the calculation processing procedure of the step four is as follows:
let the three selected feature points be P respectively 1 、P 2 、P 3 ;
From the origin O to the point P 1 A distance of (a), the origin O and the point P 1 Straight line OP 1 Has a horizontal angle of alpha 1 Azimuthal angle of beta 1 The angle of inclination being gamma 1 ;
From the origin O to the point P 2 A distance of b, the origin O and the point P 2 Straight line OP 2 Has a horizontal angle of alpha 2 Azimuthal angle of beta 2 The angle of inclination being gamma 2 ;
From the origin O to the point P 3 C, the origin O and the point P 3 Straight line OP 3 Has a horizontal angle of alpha 3 Azimuthal angle of beta 3 The angle of inclination being gamma 3 ;
A three-point structural surface equation is thus obtained:
or
|ccosγ 3 ·sinβ 3 -acosγ 1 ·sinβ 1 ccosγ 3 ·cosβ 3 -acosγ 1 ·cosβ 1 csinγ 3 -asinγ 1 |
The structural surface equation is obtained by arrangement and is A (x-x) 1 )+B(y-y 1 )+C(z-z 1 )=0
Then the structural plane normal vector N = (a, B, C);
wherein the content of the first and second substances,
the structural surface inclination angle phi is calculated as follows:
an acute angle is formed between the structural plane and the xOy plane, and an xOy plane normal vector Z = (0,0,1) is taken;
the inclination of the structure plane phi = arccos (| N · Z |/| N | -) Z |;
the structural plane tendency g is calculated as follows:
taking a normal vector n of the structural surface,
n projection on xOy plane n' = (A, B, 0)
Taking the positive Y-axis vector Y = (0,1,0)
ω=arccos(n’·Y/∣n’∣·∣Y∣)
Tendency of structural surface g
g=2π-ω(A<0)
The trajectory line equation of the structure extending towards the heading direction is as follows:
wherein e is 1 Is the horizontal distance between the survey station position and the central axis of the tunnel, e 2 Is the height of the station location.
Under the condition that the local magnetic field is interfered by a magnetic stratum, the azimuth angle influenced and measured by the magnetic field of the surrounding rock needs to be corrected through the tunneling direction, the tunneling azimuth angle is set to be theta, the tunneling azimuth angle influenced and measured by the magnetic surrounding rock is set to be theta ', delta = theta-theta', wherein delta is the declination angle of the local area, and can be obtained through inquiring topographic map data of the local area, and the calculation processing process of the fourth step is as follows:
let the three selected points be P respectively 1 、P 2 、P 3 ;
From the origin O to the point P 1 、P 2 、P 3 The distances of (a) to (c) are a, b and c respectively;
straight line OP 1 The uncorrected azimuth angle measured by the compass is beta 1 ', straight line OP 2 The uncorrected azimuth angle measured by compass is beta 2 ', straight line OP 3 The uncorrected azimuth angle measured by the compass is beta 3 ’;
Straight line OP 1 Is at an inclination angle of gamma 1 Straight line OP 2 Is at an inclination angle of gamma 2 Straight line OP 3 Is gamma 3 ;
From this, the structural surface equation can be obtained:
the structural surface equation is obtained by arrangement and is A (x-x) 1 )+B(y-y 1 )+C(z-z 1 )=0
Then the structural plane normal vector: n = (A, B, C) wherein
|bcosγ 2 ·cos(β 2 ’+δ)-acosγ 1 ·cos(β 1 ’+δ) bsinγ 2 -asinγ 1 |
A=|ccosγ 3 ·cos(β 3 ’+δ)-acosγ 1 ·cos(β 1 ’+δ) csinγ3-asinγ 1 |
The structural surface inclination angle phi is calculated as follows:
an acute angle is formed between the structural plane and the xOy plane, and an xOy plane normal vector Z = (0,0,1) is taken;
the inclination of the structure plane phi = arccos (| N · Z |/| N | -) Z |;
structural surface tendency calculation g is as follows:
taking a normal vector n of the structural surface,
n projection on xOy plane n' = (A, B, 0)
Taking the positive Y-axis vector Y = (0,1,0)
ω=arccos(n’·Y/∣n’∣·∣Y∣)
Structural plane tendency g
The trajectory line equation of the structure extending towards the tunneling direction is as follows:
wherein e is 1 E is the horizontal distance between the survey station position and the central axis of the tunnel or the horizontal distance between the survey station position and the central point of the circular arc profile of the tunnel when the survey station is at the left side of the central axis 1 Taking the positive value, when the survey station is at the right side of the central axis e 1 Take a negative value, e 2 Is the vertical distance from the measuring station position to the center point of the tunnel arc profile, e when the measuring station is below the central axis 2 Taking the positive value, when the survey station is above the central axis e 2 Taking a negative value.
The invention provides a method for establishing an orthogonal coordinate system by taking a station position as an origin O, taking an azimuth angle of 0 degrees (a positive north direction N) as a positive y-axis direction, taking an azimuth angle of 90 degrees (a positive east direction E) as a positive x-axis direction and taking a vertical direction as a positive z-axis direction. The method comprises the steps of measuring the distance, the azimuth angle, the inclination angle and the horizontal angle from a characteristic point on a structural surface to a measuring station, solving a plane equation by a three-point method, further solving the inclination and the inclination angle of the structural surface, and obtaining the exposed track equation of the structural surface by the simultaneous establishment of the plane equation and a tunnel profile equation.
The method can be used for directly measuring and calculating without re-establishing a coordinate system under the general condition. And effective correction measures are also provided for the situation that the local magnetic field is disturbed by the magnetic stratum. In addition, the method can be used for checking and supplementing azimuth measurement by measuring the horizontal angle, and the accuracy of the measurement result is effectively ensured.
The method can finish the measurement work without inputting the coordinates of the measuring station under the general condition, if the accurate position coordinates of the measuring station, the measuring points and the structural surface need to be recorded, the marking can be made at the position where the measuring station is established, the point location coordinates of the marking position can be measured by selecting a machine at the later stage, and the coordinates of each measuring point can be obtained through calculation. Effectively reduces the cross operation time and improves the working efficiency. The method is fast and convenient, and can carry out measurement without inputting coordinates of a measuring station, namely, the measurement is carried out immediately, so that the method is fast and convenient.
The equation listed in the invention takes a tunnel with a circular outline as an example, when the cross section of the tunnel is in other shapes, the equation of the corresponding tunnel outline cross section and the structural surface equation are selected for simultaneous calculation according to the shape of the cross section of the tunnel at the position of a target point.
While the preferred embodiments of the present invention have been illustrated and described, 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.
Claims (6)
1. A tunnel cave wall joint structural plane attitude measuring method is characterized by comprising the following steps: the method comprises the following measurement steps:
establishing an orthogonal coordinate system by taking the position of a measuring station as an origin O, taking an azimuth angle of 0 degrees as the positive direction of a y axis, taking an azimuth angle of 90 degrees as the positive direction of an x axis and taking the vertical direction as the positive direction of a z axis;
measuring a horizontal angle, an azimuth angle and an inclination angle of the tunneling direction of the tunnel;
selecting at least three feature points which are not on the same straight line on the structural surface trace, and respectively measuring the distance from the origin O to each feature point and the horizontal angle, the azimuth angle and the inclination angle of the connecting line of the origin and each feature point;
step four, calculating and processing the horizontal angle, the azimuth angle, the inclination angle and the distance of any three characteristic points measured in the step three to obtain the attitude information of the structural plane;
under the condition that the geomagnetic field is not interfered, the calculation processing process of the step four is as follows:
let the three selected feature points be P respectively 1 、P 2 、P 3 ;
From the origin O to the point P 1 A distance of (a), the origin O and the point P 1 Connected straight line OP of 1 Has a horizontal angle of alpha 1 Azimuthal angle of beta 1 The angle of inclination being gamma 1 ;
From the origin O to the point P 2 A distance of b, the origin O and the point P 2 Connected straight line OP of 2 Has a horizontal angle of alpha 2 Azimuthal angle of beta 2 The angle of inclination being gamma 2 ;
From the origin O to the point P 3 C, the origin O and the point P 3 Connected straight line OP of 3 Has a horizontal angle of alpha 3 Azimuthal angle of beta 3 The angle of inclination being gamma 3 ;
The three-point structural surface equation is thus obtained:
the structural surface equation is obtained by arrangement and is A (x-x) 1 )+B(y-y 1 )+C(z-z 1 )=0
Then the structural plane normal vector N = (a, B, C);
wherein the content of the first and second substances,
the structural surface inclination angle phi is calculated as follows:
an acute angle is formed between the structural plane and the xOy plane, and an xOy plane normal vector Z = (0,0,1) is taken;
the inclination of the structure plane phi = arccos (| N · Z |/| N | -) Z |;
the structural plane tendency g is calculated as follows:
taking a normal vector n of the structural surface,
n projection on xOy plane n' = (A, B, 0)
Taking the positive Y-axis vector Y = (0,1,0)
ω=arccos(n’·Y/∣n’∣·∣Y∣)
Tendency of structural surface g
The trajectory line equation of the structure extending towards the tunneling direction is as follows:
wherein e is 1 Is the horizontal distance between the survey station position and the central axis of the tunnel, e 2 Height of the station location;
under the condition that the local magnetic field is interfered by a magnetic stratum, the azimuth angle influenced and measured by the magnetic field of the surrounding rock needs to be corrected through the tunneling direction, the tunneling azimuth angle is set to be theta, the tunneling azimuth angle interfered and measured by the magnetic surrounding rock is theta ', delta = theta-theta', wherein delta is the declination angle of the local area, and can be obtained through inquiring according to topographic map data of the local area, and the calculation processing process of the fourth step is as follows:
let the three selected feature points be P respectively 1 、P 2 、P 3 ;
From the origin O to the point P 1 、P 2 、P 3 The distances of (a) to (c) are a, b and c respectively;
straight line OP 1 The uncorrected azimuth angle measured by the compass is beta 1 ', straight line OP 2 The uncorrected azimuth angle measured by the compass is beta 2 ', straight line OP 3 The uncorrected azimuth angle measured by the compass is beta 3 ’;
Straight line OP 1 Is at an inclination angle of gamma 1 Straight line OP 2 Is at an inclination angle of gamma 2 Straight line OP 3 Is at an inclination angle of gamma 3 ;
From this, the structural surface equation can be obtained:
the structural surface equation is obtained by arrangement and is A (x-x) 1 )+B(y-y 1 )+C(z-z 1 )=0
Then the structural plane normal vector: n = (A, B, C) wherein
The structural surface inclination angle phi is calculated as follows:
an acute angle is formed between the structural plane and the xOy plane, and an xOy plane normal vector Z = (0,0,1) is taken;
-structural plane inclination phi = arccos (| N-Z |/| N | Z |);
the structural plane tendency g is calculated as follows:
taking a normal vector n of the structural surface,
n projection on xOy plane n' = (A, B, 0)
Taking the positive Y-axis vector Y = (0,1,0)
ω=arccos(n’·Y/∣n’∣·∣Y∣)
Structural surface tendency g
The trajectory line equation of the structure extending towards the tunneling direction is as follows:
wherein e is 1 The horizontal distance between the measuring station position and the central axis of the tunnel or the horizontal distance between the measuring station position and the central point of the circular arc profile of the tunnel is measured, and the measuring station is positioned on the left side of the central axis e 1 Taking the positive value, when the survey station is at the right side of the central axis e 1 Take a negative value, e 2 Is the vertical distance from the measuring station position to the center point of the tunnel arc profile, e when the measuring station is below the central axis 2 Taking the positive value, when the survey station is above the central axis e 2 Taking a negative value.
2. The tunnel cave wall joint structural plane attitude measuring method according to claim 1, characterized in that: before the step one, firstly, a tripod is placed, then the measuring instrument is installed on the tripod, then the tripod and the measuring instrument are adjusted, so that bubbles of a circular level and a long level of the measuring instrument are centered, and the measuring instrument is in a horizontal state.
3. The tunnel cave wall joint structural plane attitude measuring method according to claim 2, characterized in that: in the second step, before measurement, a telescope of the measuring instrument is adjusted to enable the central axes of the ocular lens and the objective lens to be horizontal, the ocular lens points to the tunneling direction, at the moment, the horizontal angle, the azimuth angle and the inclination angle of the tunneling direction are measured, and the measuring instrument reads and records data after measurement.
4. The tunnel cave wall joint structural plane attitude measuring method according to claim 1, characterized in that: in the third step, during measurement, a coarse aiming device of the measuring instrument is firstly used for aligning a target to carry out coarse aiming, then a telescope of the measuring instrument is adjusted to align the feature points on the exposed structure surface trace in the effective measuring distance range, after the reading is stable, the horizontal angle degree, the azimuth angle degree, the inclination angle degree and the distance between the horizontal angle degree, the azimuth angle degree, the inclination angle degree and the measuring station position of the feature points are read and recorded, the steps are repeated, the horizontal angle, the azimuth angle, the inclination angle and the distance between the horizontal angle degree, the azimuth angle degree, the inclination angle degree and the measuring station position of at least three feature points are measured, and finally the measured data are input into a computing system to obtain a structure surface equation and structure surface occurrence information.
5. The method for measuring the attitude of the joint structural plane of the tunnel cave wall according to claim 4, wherein the method comprises the following steps: in the fourth step, during measurement, if the difference between the measured horizontal angle degree of the characteristic point and the measured horizontal angle degree of the tunneling direction is equal to the difference between the measured azimuth angle degree of the characteristic point and the measured azimuth angle degree of the tunneling direction, the magnetic field of surrounding rocks around the position of the measuring station is stable, and when the computing system computes and processes data, the computing system performs computing processing under the condition of no magnetic field interference;
if errors exist between the difference value of the measured horizontal angle degrees of the characteristic points and the measured horizontal angle degrees of the tunneling direction and the difference value of the measured azimuth angle degrees of the characteristic points and the measured azimuth angle degrees of the tunneling direction, the fact that the surrounding rock magnetic field around the position of the measuring station is unstable is indicated, and when the computing system computes and processes data, the computing system performs computing processing under the condition that the geomagnetic field is interfered by the magnetic stratum.
6. The tunnel hole wall joint structural plane attitude measuring method according to claim 1, characterized in that: under the condition that a local magnetic field is interfered by a magnetic stratum, when a track equation of a structure extending towards the tunneling direction is measured, the vertical distance e between a measuring instrument and the central axis of the tunnel is measured firstly 2 That is, the vertical distance between the position of the measuring station and the central axis of the tunnel is e 2 Then measuring the horizontal distance e between the position of the measuring station and the central axis of the tunnel 1 During measurement, the horizontal distances m, n and m from the position of the measuring station to the tunnel walls on the two sides of the tunnel are measured>n, to obtain e 1 And (m-n)/2, inputting the measured data into a computing system for computing to obtain a track equation of the structure extending towards the tunneling direction.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202110318613.XA CN113063397B (en) | 2021-03-25 | 2021-03-25 | Tunnel cave wall joint structural plane attitude measuring method |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202110318613.XA CN113063397B (en) | 2021-03-25 | 2021-03-25 | Tunnel cave wall joint structural plane attitude measuring method |
Publications (2)
Publication Number | Publication Date |
---|---|
CN113063397A CN113063397A (en) | 2021-07-02 |
CN113063397B true CN113063397B (en) | 2022-12-06 |
Family
ID=76561830
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202110318613.XA Active CN113063397B (en) | 2021-03-25 | 2021-03-25 | Tunnel cave wall joint structural plane attitude measuring method |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN113063397B (en) |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN114170402B (en) * | 2022-02-15 | 2022-05-10 | 南京邮电大学 | Tunnel structural plane extraction method and device |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP6103828B2 (en) * | 2012-06-18 | 2017-03-29 | 株式会社安藤・間 | Tunnel displacement measurement method |
CN103697854A (en) * | 2013-12-10 | 2014-04-02 | 广西华锡集团股份有限公司 | Method for measuring occurrence of non-contact structural surface |
CN104280013A (en) * | 2014-10-30 | 2015-01-14 | 中国电建集团成都勘测设计研究院有限公司 | Method for determining attitude of rock mass structural plane based on measurement coordinates |
CN106767672B (en) * | 2016-11-23 | 2019-02-15 | 中国电建集团成都勘测设计研究院有限公司 | The method for determining ORIENTATION OF DISCONTINUITY IN ROCK MASS based on trace |
CN108896015B (en) * | 2018-05-31 | 2020-07-17 | 长江水利委员会长江科学院 | Double-laser collimation measuring method for tunnel structural surface attitude |
-
2021
- 2021-03-25 CN CN202110318613.XA patent/CN113063397B/en active Active
Also Published As
Publication number | Publication date |
---|---|
CN113063397A (en) | 2021-07-02 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN110926468B (en) | Communication-in-motion antenna multi-platform navigation attitude determination method based on transfer alignment | |
CN106988726B (en) | High-precision borehole trajectory monitoring method | |
CN106772915B (en) | A kind of installation method of satellite benchmark prism | |
CN112378399B (en) | Coal mine tunnel tunneling robot precise positioning and orientation method based on strapdown inertial navigation and digital total station | |
CN113063397B (en) | Tunnel cave wall joint structural plane attitude measuring method | |
CN107677242B (en) | Plumb line deviation measuring device and method | |
CN111473803B (en) | Calibration method for mining laser target | |
CN111197982B (en) | Heading machine pose deviation rectifying method, system and terminal based on vision and strapdown inertial navigation | |
CN111811538A (en) | Photoelectric theodolite directional calibration method based on common stars | |
CN108507534A (en) | RTK tilt measuring methods and system | |
CN114061623A (en) | Inertial sensor zero offset error identification method based on double-antenna direction finding | |
CN110146111B (en) | Initial alignment method of centering rod | |
CN111551164A (en) | Method for compensating course effect error of rate offset frequency laser gyro north seeker | |
CN202676915U (en) | Global navigation satellite system receiver | |
KR100799536B1 (en) | Apparatus and Method for estimation of Virtual Axis Magnetic Compass Data to compensate the Tilt Error of Biaxial Magnetic Compass, and System for calculating Azimuth Angle using it | |
CN112781588B (en) | Navigation resolving method for while-drilling gyroscope positioning and orientation instrument | |
CN110242317B (en) | Transverse precision control method for shield tunnel | |
CN106968665B (en) | Method for measuring inclination of oil well by using inertial navigation system | |
CN112965091B (en) | Agricultural robot positioning method and system | |
CN115112103B (en) | LADCP and combined inertial navigation system combined observation system and method | |
CN108195402B (en) | Total station large-inclination angle measurement error analysis and correction method | |
CN115855116B (en) | Error calibration process generation method and system | |
CN113375692B (en) | Method for rapidly evaluating calibration precision of fiber-optic gyroscope | |
JPH0814903A (en) | Surveying instrument | |
CN112697140B (en) | Measuring device and measuring and calculating method for attitude angle of inertial navigation IMU (inertial measurement unit) component relative to inner ring frame |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PB01 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
GR01 | Patent grant | ||
GR01 | Patent grant |