CN208902047U - Three-D displacement demarcates frame and measuring system - Google Patents

Abstract

The utility model discloses three-D displacement calibration frame and measuring systems, are related to Geotechnical Monitoring technical field.A kind of three-D displacement calibration frame, including loading plate, vertical plate and multiple calibration sticks.Vertical plate is fixedly connected on loading plate, and vertical plate is perpendicular to loading plate.A plurality of first scale and a plurality of second scale are provided on vertical plate.A plurality of first scale is parallel to loading plate setting, and is spaced setting.A plurality of second scale is arranged perpendicular to loading plate, and is spaced setting.A plurality of first scale and a plurality of second scale intersect in net form.First scale and the second scale intersection crunode offer calibration hole compatible with calibration stick, and vertical plate is run through perpendicular to vertical plate in calibration hole.A kind of measuring system, which employs above-mentioned three-D displacements to demarcate frame.The in-site measurement precision of three-D displacement calibration frame and measuring system energy service hoisting optical measuring instrument provided by the utility model.

Description

Three-D displacement demarcates frame and measuring system

Technical field

The utility model relates to Geotechnical Monitoring technical field, in particular to three-D displacement demarcate frame and Measuring system.

Background technique

Due to geotechnical engineering construction or geological disaster, Rock And Soil will appear certain deformation, when deformation increases simultaneously After early warning value, the safety of engineering structure and surrounding enviroment will be jeopardized.Therefore, it is necessary to real to Rock And Soil and protected object Safety monitoring is applied, the deformation process of monitoring object is grasped, to ensure the safety of protected object.

Surface deformation is the important indicator of geotechnical engineering stability, during engineering construction, passes through measurement monitoring pair The three-D displacement of elephant obtains the displacement total amount of monitoring point and interim monitoring rate in monitoring cycle, by controlling mark with monitoring Quasi- value compares, for evaluating the safety of monitoring object, to guarantee engineering construction safety and operational safety in the future.

In geotechnical engineering, the three-dimensional coordinate of high precision total station (or theodolite) measurement monitoring object is generallyd use, is led to The three-dimensional coordinate compared in different monitoring time the same coordinate systems is crossed, the three-D displacement of monitoring object can be obtained.With at As the development of technology and electronic computer technology, close-range photogrammetry progresses into geotechnical engineering monitoring field, and the technology is main Solve corresponding space multistory coordinate (plane coordinates and elevation) according to plane picpointed coordinate, by establish pixel coordinate point and by Corresponding mathematical relationship between object corresponding coordinate point is taken the photograph, coordinate solution is carried out.

" building deformation measurement specification " JGJ8-2016 is to foundation, side slope, foundation pit, pipeline, underground engineering facility, city The engineerings such as city's infrastructure give different measurement grade and precision index, almost cover Geotechnical Monitoring range.

From existing research report, no matter high precision total station (or theodolite) technology or photogrammetric technology at the scene Precision in measurement application is mm class precision, if its measurement accuracy under the complicated field condition such as rainfall, haze, strong wind, burning sun It can be lower.

Utility model content

The purpose of this utility model is to provide a kind of three-D displacements to demarcate frame, and energy auxiliary optical measuring instrument is surveyed Amount, improves the in-site measurement precision of optical measuring instrument.

The utility model provides a kind of technical solution:

A kind of three-D displacement calibration frame, including loading plate, vertical plate and multiple calibration sticks.The vertical plate is fixedly connected on described Loading plate, and the vertical plate is perpendicular to loading plate.A plurality of first scale and a plurality of second scale are provided on the vertical plate.It is more First scale described in item is parallel to the loading plate setting, and is spaced setting.A plurality of second scale is perpendicular to the carrying Plate setting, and it is spaced setting.A plurality of first scale and a plurality of second scale intersect in net form.First quarter Degree and second scale intersection crunode offer calibration hole compatible with the calibration stick, and the calibration hole is perpendicular to described Vertical plate runs through the vertical plate.

Further, a plurality of first scale spaced set.

Further, a plurality of second scale spaced set.

Further, the vertical plate is two pieces, and two pieces of vertical plates are arranged at intervals on the loading plate, and two pieces of institutes Vertical plate is stated to be parallel to each other.Multiple calibration holes on two pieces of vertical plates correspond.

Further, the vertical plate with a thickness of 6mm, length 315mm, width 300mm, between two pieces of vertical plates Distance be 100mm.The loading plate with a thickness of 15mm.

Further, multiple scale groups are provided on the calibration stick, multiple scale group interval settings are each described Scale group includes two third scales, and the distance between two described third scales are 6mm, and the depth of the third scale is 0.5mm.The length of the calibration stick is 200mm.

Further, the end face center at the calibration stick both ends offers orthogonal crosshair, the crosshair Width is 1mm, depth 2mm.

Further, the diameter in the calibration hole is 10mm.The diameter of the calibration stick is 10mm.

Further, the width of first scale is 1mm, depth 2mm.The width of second scale is 1mm, deep Degree is 2mm.

Compared with prior art, the beneficial effect of three-D displacement calibration frame provided by the utility model is:

Three-D displacement calibration frame provided by the utility model can be inserted by the way that three calibration sticks are passed through three calibration holes respectively Enter into vertical plate, and two of them calibration stick is located on the first scale of same, two of them are located at the second scale of same On, three calibration sticks just can be made to surround right angled triangle.Wherein, it can be demarcated by two be located on the first scale of same Correction coefficient on stick subsidiary first direction；Pass through the two calibration stick subsidiaries the being located on the second scale of same Correction coefficient on two directions；The correction coefficient on the length subsidiary third direction of vertical plate is stretched out by calibration stick.In turn Accurately by the correction coefficient auxiliary optical measuring instrument on first direction perpendicular to each other, in second direction and on third direction Measurement improves the accuracy of optical measuring instrument in-site measurement.

The another object of the utility model is to provide a kind of measuring system, is capable of measuring and calculates 3 D displacement correcting Coefficient, convenient for improving the in-site measurement precision of optical measuring instrument by the 3 D displacement correcting coefficient.

The utility model provides a kind of technical solution:

A kind of measuring system, including three-D displacement demarcate frame.Three-D displacement calibration frame includes loading plate, vertical plate and more A calibration stick.The vertical plate is fixedly connected on the loading plate, and the vertical plate is perpendicular to loading plate.It is arranged on the vertical plate There are a plurality of first scale and a plurality of second scale.A plurality of first scale is parallel to the loading plate setting, and is spaced setting. A plurality of second scale is arranged perpendicular to the loading plate, and is spaced setting.A plurality of first scale and a plurality of described Two scales intersect in net form.First scale and second scale intersection crunode are offered and are mutually fitted with the calibration stick The vertical plate is run through perpendicular to the vertical plate in the calibration hole matched, the calibration hole.

Compared with prior art, the beneficial effect of 3 D displacement correcting coefficient measuring method provided by the utility model with it is above-mentioned The beneficial effect of the three-D displacement calibration stick of offer compared with the existing technology is identical, and details are not described herein.

Detailed description of the invention

It, below will be to use required in embodiment in order to illustrate more clearly of the technical solution of the utility model embodiment Attached drawing be briefly described.It should be appreciated that the following drawings illustrates only some embodiments of the utility model, therefore should not be by Regard the restriction to range as.For those of ordinary skill in the art, without creative efforts, may be used also To obtain other relevant attached drawings according to these attached drawings.

Fig. 1 is the structural schematic diagram that the three-D displacement that the first embodiment of the utility model provides demarcates the first visual angle of frame；

Fig. 2 is the structural schematic diagram that the three-D displacement that the first embodiment of the utility model provides demarcates the second visual angle of frame；

Fig. 3 is the structural schematic diagram that the three-D displacement that the first embodiment of the utility model provides demarcates frame third visual angle；

Fig. 4 is the structural schematic diagram for the calibration stick that the first embodiment of the utility model provides；

Fig. 5 is the flow chart for the 3 D displacement correcting coefficient measuring method that the second embodiment of the utility model provides.

Icon: 10- three-D displacement demarcates frame；100- loading plate；200- vertical plate；The first scale of 210-；The second scale of 220-； 230- demarcates hole；300- demarcates stick；310- scale group；311- third scale.

Specific embodiment

It is practical new below in conjunction with this to keep the objectives, technical solutions, and advantages of the embodiments of the present invention clearer Attached drawing in type embodiment, the technical scheme in the utility model embodiment is clearly and completely described.Obviously, it is retouched The embodiment stated is the utility model a part of the embodiment, instead of all the embodiments.Usually here in attached drawing description and The component of the utility model embodiment shown can be arranged and be designed with a variety of different configurations.

Therefore, requirement is not intended to limit to the detailed description of the embodiments of the present invention provided in the accompanying drawings below The scope of the utility model of protection, but it is merely representative of the selected embodiment of the utility model.Based in the utility model Embodiment, every other embodiment obtained by those of ordinary skill in the art without making creative efforts, all Belong to the range of the utility model protection.

It should also be noted that similar label and letter indicate similar terms in following attached drawing, therefore, once a certain Xiang Yi It is defined in a attached drawing, does not then need that it is further defined and explained in subsequent attached drawing.

In the description of the present invention, it should be understood that term " on ", "lower", "inner", "outside", "left", "right" etc. The orientation or positional relationship of instruction be based on the orientation or positional relationship shown in the drawings or the utility model product use when The orientation or positional relationship that the orientation or positional relationship or those skilled in the art usually put usually understand, be only for Convenient for description the utility model and simplify description, rather than the equipment of indication or suggestion meaning or element must have specifically Orientation is constructed and operated in a specific orientation, therefore should not be understood as limiting the present invention.

In addition, term " first ", " second " etc. are only used for distinguishing description, it is not understood to indicate or imply relatively important Property.

In the description of the present invention, it should also be noted that, unless otherwise clearly defined and limited, " setting ", Terms such as " connections " shall be understood in a broad sense, for example, " connection " may be a fixed connection, may be a detachable connection, or one Ground connection；It can be mechanical connection, be also possible to be electrically connected；Can be and be directly connected to, can also by between intermediary in succession It connects, can be the connection inside two elements.For the ordinary skill in the art, can understand as the case may be The concrete meaning of above-mentioned term in the present invention.

With reference to the accompanying drawing, specific embodiment of the present utility model is described in detail.First embodiment

Referring to Fig. 1, providing a kind of three-D displacement calibration frame 10 in the present embodiment, it to be used for auxiliary optical measuring instrument (not shown) measures.Wherein, 10 energy auxiliary optical measuring instrument of three-D displacement calibration frame measures, and improves optical measurement The in-site measurement precision of instrument.

Wherein, what optical measuring instrument referred to is total station, theodolite or the digital phase using close shot videographic measurment technology The displacement measuring instrument that machine etc. is measured based on optical imaging concept.

It should be noted that optical measuring instrument is in the monitoring of ground safety engineering for monitoring the deformation of ground, measurement prison Survey the three-D displacement of object.Wherein the three-D displacement of monitoring object can be by monitoring object in orthogonal three directions Displacement embodies, and monitoring object can be measured by optical measuring instrument on orthogonal first direction, in second direction With the displacement on third direction, to judge the safe condition of monitoring object.

In the present embodiment, it is possible to which demarcating frame 10 by three-D displacement provides first direction, second direction to optical measuring instrument With the correction coefficient on third direction so that the number that measure for monitoring object of optical measuring instrument can be corrected by correction coefficient According to, and then improve the precision that optical measuring instrument measures monitoring object.

Please refer to Fig. 1, Fig. 2, Fig. 3 and Fig. 4, wherein it includes loading plate 100, vertical plate 200 that three-D displacement, which demarcates frame 10, With multiple calibration sticks 300.

Wherein, vertical plate 200 is fixedly installed on loading plate 100, and vertical plate 200 is perpendicular to loading plate 100.By holding Support plate 100 provides carrying supporting role to vertical plate 200, guarantees the stabilization of vertical plate 200.Further, it is provided on vertical plate 200 more The first scale of item 210 and a plurality of second scale 220, the i.e. wherein side of vertical plate 200 are provided with a plurality of first scale 210 and a plurality of Second scale 220.A plurality of first scale 210 is parallel to the setting of loading plate 100, and is spaced and sets between a plurality of first scale 210 It sets；In addition, a plurality of second scale 220 is arranged perpendicular to loading plate 100, and the setting of a plurality of second scale 220 interval.Wherein, A plurality of first scale 210 and a plurality of second scale 220 intersect in net form, and 220 phase of the first scale 210 and the second scale Mutual crosspoint offers calibration hole 230, and calibration hole 230 is adapted with calibration stick 300, and demarcates hole 230 perpendicular to vertical plate 200 Through vertical plate 200.Calibration hole 230 can be passed through to be removably installed on vertical plate 200 by demarcating stick 300 then.

It should be noted that in the present embodiment, corresponding numerical value is all set on every first scale 210, every two article The distance between one scale 210 is the absolute value of the difference of the two corresponding numerical value of the first scale 210；Similarly, every Corresponding numerical value is both provided on two scales 220, the distance between every two second scales 220 are two the second scales 220 The absolute value of the difference of corresponding numerical value.

Further, in the present embodiment, a plurality of first scale, 210 spaced set, so that a plurality of first scale 210 The distance between convenient for calculating, and opened up on vertical plate 200 convenient for the first scale 210.That is corresponding on every first scale 210 Numerical value formed arithmetic progression, for example, 0,5,10,15,20 ... etc..

It should be appreciated that in other embodiments, the mutual distance of a plurality of first scale 210 can be uneven, for example, The corresponding numerical value of a plurality of first scale 210 is 0,1,2,5,10,12,15,16,20 ... etc..

In addition, in the present embodiment, a plurality of second scale, 220 spaced set, so that between a plurality of second scale 220 Distance convenient for calculating, and opened up on vertical plate 200 convenient for the second scale 220.That is, corresponding on every second scale 220 Numerical value forms arithmetic progression, for example, -15, -10, -5,0,5,10,15 ... etc..

It should be appreciated that in other embodiments, the mutual distance of a plurality of second scale 220 can also be uneven, example Such as, the corresponding numerical value of a plurality of second scale 220 is -10, -5, -2, -1,0,1,2,5,10,12 ... etc..

Similarly, multiple scale groups 310, the setting of multiple intervals of scale group 310 are provided on calibration stick 300.In addition, each Scale group 310 includes two third scales 311, two interval of third scale 311 settings.In the present embodiment, two it is adjacent The distance between scale group 310 be greater than the distance between two third scales 311 in same group of scale group 310.Wherein, every Third scale 311 is correspondingly arranged a numerical value.The numerical value is third scale 311 to the calibration one of end of stick 300 Distance, while being also convenient for calculating the distance between any two third scales 311.

Wherein, in the present embodiment, it is possible to pass through the mark for demarcating hole 230 and being inserted into vertical plate 200, and making for stick 300 is demarcated Determine stick 300 and protrudes from vertical plate 200.Specifically, three calibration sticks 300 are inserted into vertical plate 200, and make two of them mark Determine stick 300 to be located on the first scale of same 210, so that two of them calibration stick 300 is located on the second scale of same 220, Just three calibration sticks 300 can be made to form right angled triangle.Just it can be demarcated by two be located on the first scale of same 210 Measurement on 300 auxiliary optical measuring instrument first direction of stick guarantees the precision measured on optical measuring instrument first direction；Pass through The measurement in two calibration 300 auxiliary optical measuring instrument second directions of stick on the second scale of same 220, guarantees optics The hard-cover degree measured in measuring instrument second direction；By the calibration stretching vertical plate 200 of stick 300 apart from auxiliary optical measuring instrument third The measurement in direction guarantees the precision measured on optical measuring instrument third direction.So that the in-site measurement essence of optical measuring instrument Degree is improved.

In addition, in the present embodiment, the quantity of vertical plate 200 is two pieces, and two pieces of vertical plates 200 are arranged at intervals at loading plate 100 On.Also, multiple calibration holes 230 on two pieces of vertical plates 200 correspond respectively, and calibration stick 300 can be made to sequentially pass through two When a corresponding calibration hole 230, it equally can guarantee calibration stick 300 perpendicular to vertical plate 200.By the setting of two pieces of vertical plates 200, It can guarantee that calibration stick 300 guarantees the stabilization of calibration stick 300 when penetrating to two and demarcating in hole 230, be avoided that calibration stick 300 produces Life deflects and causes the not accurate of measurement.

In the present embodiment, vertical plate 200 with a thickness of 6mm, length 315mm, width 300mm, and two vertical plates The distance between 200 be 100mm.In addition, the width of loading plate 100 is 100mm, with a thickness of 15mm, length 300mm.Wherein, Two pieces of vertical plates 200 are respectively arranged at the two sides of 100 width direction of loading plate, and with two on 100 length direction of loading plate End face is equal.Meanwhile two pieces of vertical plates 200 are equal with the bottom surface of loading plate 100, so that two pieces of vertical plates 200 are installed on carrying After plate 100, so that the part that two pieces of vertical plates 200 protrude from loading plate 100 forms the square of 300mm*300mm.In addition, In the present embodiment, vertical plate 200 and loading plate 100 are realized in such a way that screw is fixed and are detachably connected, i.e. screw is from loading plate 100 width direction is through vertical plate 200 and is connected to loading plate 100, it should be understood that in other embodiments, can also pass through Other modes realize the connection of vertical plate 200 and loading plate 100, for example, riveting or clamping etc..

In addition, in the present embodiment, the internal diameter in calibration hole 230 is 10mm, similarly, the diameter of calibration stick 300 is 10mm, is protected Card calibration stick 300 and the adaptation for demarcating hole 230, so that calibration stick 300 can guarantee calibration when being inserted into calibration hole 230 The stabilization of stick 300.It should be appreciated that in other embodiments, calibration hole 230 and calibration stick 300 can also be sized to Other numerical value, for example, 2mm, 5mm or 12mm etc..I.e., it is possible to which the diameter of the internal diameter for demarcating hole 230 and calibration stick 300 is set It is set to and is less than or equal to 15mm.In addition, in the present embodiment, the length of calibration stick 300 is 200mm.

Further, in the present embodiment, the distance between two third scales 311 in the same scale group 310 For 6mm, i.e. the distance between two third scales 311 are inserted into mark so that working as and demarcating stick 300 equal to the thickness of vertical plate 200 When determining the inside in hole 230, two scales in the same scale group 310 can be made equal with two sides of vertical plate 200 respectively, The measurement of 200 distance of vertical plate can be stretched out convenient for calibration 300 both ends of stick.It should be appreciated that in other embodiments, the thickness of vertical plate 200 The distance between two third scales 311 may be set to be other numerical value in degree and same group of scale group 310, such as 5mm, 4mm or 8mm etc..

In addition, in the present embodiment, width 1mm, the depth 2mm of the first scale 210；The width of second scale 220 is 1mm, depth 2mm；The depth of third scale 311 is 0.5mm.In addition, in the present embodiment, demarcating the end face at 300 both ends of stick On offer orthogonal crosshair, in order to optical measuring instrument in measurement data for demarcate stick 300 positioning.Its In, the depth of crosshair is 2mm, and the width of crosshair is 1mm.It should be noted that wherein, what crosshair referred to is shape At two silks of cross shape, i.e., there are two orthogonal crosshair, two crosshairs for setting on the end face of calibration stick 300 Cross is collectively formed, in order to which " ten " word formed by two crosshairs measures positioning.

The three-D displacement calibration frame 10 provided in the present embodiment can be by demarcating three calibration sticks 300 by three respectively Hole 230 is inserted into vertical plate 200, and two of them calibration stick 300 is located on the first scale of same 210, two of them position In three calibration sticks 300 on the second scale of same 220, just can be made to surround right angled triangle.It wherein, can be same by being located at The correction coefficient on two calibration 300 subsidiary first directions of stick on the first scale of item 210；By being located at same second The correction coefficient in two calibration 300 subsidiary second directions of stick on scale 220；Vertical plate 200 is stretched out by calibration stick 300 Length subsidiary third direction on correction coefficient.And then by first direction perpendicular to each other, in second direction and Correction coefficient auxiliary optical measuring instrument on third direction accurately measures, and improves the accuracy of optical measuring instrument in-site measurement.

Second embodiment

Fig. 1, Fig. 4 and Fig. 5 are please referred to, a kind of 3 D displacement correcting coefficient measuring method is provided in the present embodiment, Which employs the three-D displacements provided in optical measuring instrument and first embodiment to demarcate frame 10.3 D displacement correcting coefficient measurement Method is capable of measuring and calculates 3 D displacement correcting coefficient, convenient for improving optical measuring instrument by the 3 D displacement correcting coefficient In-site measurement precision.

Wherein, 3 D displacement correcting coefficient measuring method includes:

S101, three calibration sticks 300 are inserted into respectively in three calibration holes 230.Wherein, in three calibration holes 230, wherein Two are located on the first scale of same 210, and two of them are located on the second scale of same 220.

By above-mentioned set-up mode, three calibration sticks 300 can be made to surround right angled triangle, and make two of them Calibration stick 300 on the first scale of same 210 can be parallel to loading plate 100, convenient for the correction coefficient on first direction Measurement；Wherein it is located at the line of two calibration sticks 300 on the second scale of same 220 perpendicular to loading plate 100, can be convenient for The measurement of the correction coefficient of second direction.In addition, in the present embodiment, it is also necessary to calibration stick 300 is protruded from into vertical plate 200, with So that convenient for protruding from the correction coefficient on the linear measure longimetry third direction of vertical plate 200 by demarcating stick 300.

S102, the distance that stick 300 is demarcated by two on optical measuring instrument measurement the first scale of same 210, obtain First measured value.

S103, the distance that stick 300 is demarcated by two on optical measuring instrument measurement the second scale of same 220, obtain Second measured value.

S104, the length that calibration stick 300 stretches out vertical plate 200 is measured by optical measuring instrument, obtain third measured value.

It should be noted that can be the length that the one of calibration stick 300 of measurement stretches out vertical plate 200 in step S104, It is also possible to measure the length that two of them calibration stick 300 stretches out vertical plate 200.In the present embodiment, step S104 includes:

Three calibration sticks 300 are measured to stretch out the length of vertical plate 200 and obtain three third measured values respectively.

In addition, in the present embodiment, step S102, the sequence of step S103 and step S104 can be interchanged.

S105, the actual range for calculating two calibration sticks 300 being located on the first scale of same 210, obtain the first base Quasi- value.

It should be noted that the actual range for two calibration sticks 300 being located on the first scale of same 210 is two Demarcate the absolute value of the difference of two corresponding values of the second scale 220 where stick 300.

S106, the actual range for calculating two calibration sticks 300 being located on the second scale of same 220, obtain the second base Quasi- value.

It should be noted that the actual range for two calibration sticks 300 being located on the second scale of same 220 is two Demarcate the absolute value of the difference of two corresponding values of the first scale 210 where stick 300.

S107, the actual range that calibration stick 300 stretches out vertical plate 200 is calculated, obtains third a reference value.

It should be noted that the actual range that calibration stick 300 stretches out vertical plate 200 can be corresponding by third scale 311 Value is determined.

In addition, stretching out the calculating of the actual range of vertical plate 200 for calibration stick 300, can be for one of calibration Stick 300 is calculated, and is also possible to calculate two of them calibration stick 300.It should be noted that in the present embodiment In, the actual range for stretch out vertical plate 200 to three calibration sticks 300 calculates, and obtains three third a reference values.

It should be noted that sequence can be interchanged in step S105, step S106 and step S107.

S108, correction coefficient, the correction coefficient of the correction coefficient of second direction and third direction for calculating first direction.

Wherein, the calculation of the correction coefficient of first direction is to calculate the ratio of the first measured value and first reference value, Obtain the correction coefficient of first direction.

The calculation of the correction coefficient of second direction is to calculate the ratio of the second measured value and the second a reference value, that is, obtain Obtain the correction coefficient of second direction.

The calculation of the correction coefficient of third direction is to calculate the ratio of third measured value and third a reference value, that is, obtain Obtain the correction coefficient of third direction.

It should be noted that wherein, the calculation for the correction coefficient of third direction is specifically, calculate corresponding The ratio of third measured value and third a reference value obtains three correction coefficient initial values, calculates being averaged for three correction coefficient initial values Value, obtains the correction coefficient of third direction.

Pass through the correction coefficient of the above-mentioned first direction being calculated, the correction coefficient of second direction and third direction Correction coefficient, can be after measuring monitoring object by optical measuring instrument, by the correction coefficient of first direction to prison The displacement for surveying object first direction is modified, and can obtain monitoring object more accurately displacement in a first direction； Similarly, the displacement by the correction coefficient of second direction to monitoring object in second direction is modified, and can be monitored Object more accurately displacement in a second direction；In addition, by the correction coefficient of third direction to monitoring object in third The displacement in direction is modified, and can obtain monitoring object more accurately displacement on third direction.Just it realizes and mentions The purpose of high optical measuring instrument in-site measurement accuracy.

It should be noted that assume that the correction coefficient of first direction is obtained by the first measured value divided by first reference value, So in the amendment to monitoring object actual displacement amount, it is modified by measured value divided by the correction coefficient of first direction； , whereas if the correction coefficient of first direction is obtained by first reference value divided by the first measured value, then to monitoring object When the amendment of actual displacement amount, it is modified by measured value multiplied by the correction coefficient of first direction.Similarly, the school of second direction Positive coefficient and the correcting mode of the correction coefficient of third direction are identical with the correcting mode of the correction coefficient of first direction, herein not It repeats again.

The 3 D displacement correcting coefficient measuring method provided in the present embodiment can use optical measuring instrument and first embodiment Middle offer three-D displacement calibration frame 10 measure optical measuring instrument in a first direction, on three directions of second direction and third direction Correction coefficient, and the actual measurement data of optical measuring instrument is modified by the correction coefficient on three directions, just can Improve the in-site measurement precision of optical measuring instrument.

3rd embodiment

A kind of measuring system (not shown) is provided in the present embodiment, is used for the measurement of auxiliary optical measuring instrument, and apply In ground safety monitoring project technology.The measuring system uses the three-D displacement calibration frame 10 provided in first embodiment.And And the measuring system can be corrected the survey of coefficient by the 3 D displacement correcting coefficient measuring method provided in second embodiment Amount.The measuring system can improve the in-site measurement precision of optical measuring instrument.

The above descriptions are merely preferred embodiments of the present invention, is not intended to limit the utility model, for this For the technical staff in field, various modifications and changes may be made to the present invention.It is all in the spirit and principles of the utility model Within, any modification, equivalent replacement, improvement and so on should be included within the scope of protection of this utility model.

Claims (10)

1. a kind of three-D displacement demarcates frame, which is characterized in that including loading plate, vertical plate and multiple calibration sticks；

The vertical plate is fixedly connected on the loading plate, and the vertical plate is perpendicular to loading plate；

A plurality of first scale and a plurality of second scale are provided on the vertical plate；A plurality of first scale is parallel to the carrying Plate setting, and it is spaced setting；A plurality of second scale is arranged perpendicular to the loading plate, and is spaced setting；A plurality of described One scale and a plurality of second scale intersect in net form；

First scale and second scale intersection crunode offer calibration hole compatible with the calibration stick, the mark Hole is determined perpendicular to the vertical plate and through the vertical plate.

2. three-D displacement according to claim 1 demarcates frame, which is characterized in that a plurality of first scale is equidistantly set It sets.

3. three-D displacement according to claim 1 demarcates frame, which is characterized in that a plurality of second scale is equidistantly set It sets.

4. three-D displacement according to claim 1 demarcates frame, which is characterized in that the vertical plate is two pieces, and two pieces described vertical Plate is arranged at intervals on the loading plate, and two pieces of vertical plates are parallel to each other；Multiple marks on two pieces of vertical plates Determine hole one-to-one correspondence.

5. three-D displacement according to claim 4 demarcates frame, which is characterized in that the vertical plate with a thickness of 6mm, length is 315mm, width 300mm, the distance between two pieces of described vertical plates are 100mm；

The loading plate with a thickness of 15mm.

6. three-D displacement according to claim 1 demarcates frame, which is characterized in that be provided with multiple scales on the calibration stick Group, the setting of multiple scale group intervals, each scale group include two third scales, between two third scales Distance be 6mm, the depth of the third scale is 0.5mm；

The length of the calibration stick is 200mm.

7. three-D displacement according to claim 1 demarcates frame, which is characterized in that the end face center at the calibration stick both ends is opened Equipped with orthogonal crosshair, the width of the crosshair is 1mm, depth 2mm.

8. three-D displacement according to claim 1 demarcates frame, which is characterized in that the diameter in the calibration hole is 10mm；Institute The diameter for stating calibration stick is 10mm.

9. three-D displacement according to claim 1 demarcates frame, which is characterized in that the width of first scale is 1mm, deep Degree is 2mm；

The width of second scale is 1mm, depth 2mm.

10. a kind of measuring system, which is characterized in that including the three-D displacement calibration as described in any one of claim 1-9 Frame.