CN202599385U - Continuous anchor cable on-way displacement measuring instrument - Google Patents

Abstract

Disclosed is a continuous anchor cable on-way displacement measuring instrument which is capable of measuring continuously, wide in measuring range, high in automation degree and low in cost. The continuous anchor cable on-way displacement measuring instrument comprises a measuring device, a data transmission device and a data analysis device. The measuring device comprises a measuring unit which is composed of a casing PVC pipe, an MEMS acceleration sensor and a data line, wherein the MEMS acceleration sensor is arranged in the casing PVC pipe and is connected with the data line. The data transmission device comprises a data acquisition device, a wireless transmitter, a wireless receiver, a data memory and a solar cell, wherein the data acquisition device is connected with the measuring device, the wireless transmitter and the solar cell respectively, the data memory is connected with the data analysis device, the wireless receiver and the solar cell respectively, data is transmitted and received through the wireless transmitter and the wireless receiver respectively, and the data acquisition device is connected with the data analysis device.

Description

Anchor cable is along journey continuous dislocation measuring instrument

Technical field

The utility model belongs to technical field of measuring, relates to a kind of anchor cable particularly along journey continuous dislocation measuring instrument, and its surface that can be used for measuring anchor cable or anchor pole is out of shape along journey.

Background technology

Rubble flow, side slope unstability are common geologic hazards at present.If can before it takes place, monitor, will take measures in advance, thereby loss dropped to minimum.The deformation monitoring of buildings is an important means of safety management.The inclination and distortion of monitoring high slope and buildings generally adopts tiltmeter etc. at present.These measuring instruments generally adopt spot measurement, and measurement range is limited, are difficult to robotization, and cost is very high.

Summary of the invention

The technology of the utility model is dealt with problems and is: overcome the deficiency of prior art, a kind of continuous coverage is provided, measurement range is big, automaticity is high, lower-cost anchor cable is along journey continuous dislocation measuring instrument.

The technical solution of the utility model is: this anchor cable is along journey continuous dislocation measuring instrument; Comprise measurement mechanism, data transmission device, data analysis set-up; Measurement mechanism is made up of measuring unit; Measuring unit comprises shell pvc pipe, MEMS acceleration transducer and data line, and the MEMS acceleration transducer is in the shell pvc pipe and be connected with data line; Data transmission device comprises data acquisition unit, wireless launcher, wireless receiver, data-carrier store and solar cell; Data acquisition unit links to each other with measurement mechanism, wireless launcher, solar cell respectively; Data-carrier store links to each other with data analysis set-up, wireless receiver, solar cell respectively; Through wireless launcher and wireless receiver transceive data, data acquisition unit links to each other with data analysis set-up.

Owing to adopting solar cell to need not extra power supply,, realize unmanned, fixed time interval survey record so the field works alone for a long time; The transmission of data can be delivered to data analysis set-up through data line, also can adopt GPRS or wireless ethernet and less radio-frequency to be delivered to data analysis set-up; Because measuring unit uses the MEMS acceleration transducer; Inclination angle that just can the perception shell also is converted into digital signal; Pass to data analysis set-up through data acquisition unit, data transmission device again; Just can realize the automatic measurement of anchor cable along the journey continuous dislocation, and this measuring instrument is provided with the prior art of a plurality of tiltmeters, cost is much lower.

Description of drawings

Fig. 1 shows according to the anchor cable of the utility model structural representation along the measurement mechanism of journey continuous dislocation measuring instrument;

Fig. 2 shows according to the anchor cable of the utility model structure partial enlarged diagram along the MEMS acceleration transducer of journey continuous dislocation measuring instrument;

Fig. 3 shows the cross sectional representation according to the measurement mechanism of the utility model;

Fig. 4 shows employing according to the anchor cable of the utility model one-piece construction synoptic diagram along journey continuous dislocation measuring instrument;

Fig. 5 shows the anchor cable that adopts the utility model and calculates synoptic diagram along the displacement of a measuring unit of journey continuous dislocation measuring instrument;

The anchor cable that Fig. 6 shows the utility model is applied to the analysis synoptic diagram of slope failure along journey continuous dislocation measuring instrument.

Embodiment

Like Fig. 1, shown in 4; This anchor cable is along journey continuous dislocation measuring instrument; Comprise measurement mechanism 10, data transmission device, data analysis set-up 12; Measurement mechanism is made up of measuring unit 4, and measuring unit comprises shell pvc pipe 1, MEMS acceleration transducer 2 and data line 5, and MEMS acceleration transducer 2 is in the shell pvc pipe and be connected with data line 5; Data transmission device comprises data acquisition unit 13, wireless launcher 8, wireless receiver 11, data-carrier store 14 and solar cell 9; Data acquisition unit 13 links to each other with measurement mechanism 10, wireless launcher 8, solar cell 9 respectively; Data-carrier store 14 links to each other with data analysis set-up 12, wireless receiver 11, solar cell 9 respectively; Through wireless launcher 8 and wireless receiver 11 transceive data, data acquisition unit 13 links to each other with data analysis set-up 12.

MEMS (as shown in Figure 2) is exactly the small mechanism of integrated machinery and electronic devices and components on a silicon substrate in fact, and perhaps increasing new structural sheet makes the MEMS product with mechanical part use micromechanical process through electronic section being used semiconductor technology.MEMS mainly comprises several parts such as micro mechanism, microsensor, miniature actuator and corresponding treatment circuit, and it is to merge multiple Micrometer-Nanometer Processing Technology, and the high-tech front subject that grows up on the basis of the newest fruits of applying modern information technology.A brand-new technology field and industry have been opened up in the development of MEMS technology, and the microsensor of employing MEMS fabrication techniques, microactrator, micro parts, Micromechanical Optics device, vacuum microelectronic device, power electronic devices etc. all have very wide application prospect in Aero-Space, automobile, biomedicine, environmental monitoring, military affairs and other a lot of fields.The MEMS acceleration transducer that uses in the utility model is one of them very little application branch; The MEMS acceleration transducer is microelectromechanical systems (Micro-Electro-Mechanical-System) acceleration transducer; Inclination angle that can the perception shell also is converted into digital signal, again through data acquisition unit 13, wireless receiver 11 and Long-distance Control microcomputer UNICOM.

Preferably, the quantity of measuring unit 4 is a plurality of, MEMS acceleration transducer 2 series connection in each measuring unit 4, and through steel wire 3 and data line 5 connections.

Preferably, the quantity of the MEMS acceleration transducer 2 in each measuring unit is 2, and purpose is to measure the inclination angle of (E and N) on two orthogonal directionss respectively.

Preferably, MEMS acceleration transducer 2 is at the center of shell pvc pipe 1, because that adopt is PVC, ignores the distortion of pvc pipe, and MEMS acceleration transducer 2 is placed in the middle of the pvc pipe, can record pvc pipe inclination angle of (E and N) on two orthogonal directionss accurately; While can be avoided the MEMS acceleration transducer to be interfered or destroy.

Preferably, as shown in Figure 3, be provided with fiber protective sleeve 6 and flexible high molecular material layer 7 in the inside of shell pvc pipe 1.

Preferably, data analysis set-up 12 comprises server.

The principle of the measuring unit Displacement Measurement of the utility model is adopted in explanation below:

1. the displacement of single hop measuring unit is calculated:

Getting one section measuring unit such as Fig. 5, suppose that original AB axle is vertical, is that the Z axle is set up rectangular coordinate system in space with rod piece A B, among the definition plane X AY, is N with X axle positive dirction, and Y axle positive dirction is E.If the A point is displacement " a 0 " point, behind elapsed-time standards Δ t, the inclination angle of actual measurement rod member is changed to Δ θ _NWith Δ θ _E, wherein: B ' holds the position after changing, B for B ₁Be the projection of B ' on plane X AZ, B ₂Be the projection of B ' in the YAZ of plane, B ₃For B ' on the plane B ₁B ' B ₂Intersection point with the AB axle; Δ θ _NBe variable angle (∠ BAB along North and South direction ₁), Δ θ _EBe variable angle (∠ BAB along east-west direction ₂); In the XAZ plane, B ₁B ₃For B holds along the displacement on the North and South direction, be designated as Δ B _NIn the YAZ plane, B ₂B ₃For of the displacement of B end, be designated as Δ B along east-west direction _E, BB ₃For after B end changes to B ', the displacement on the vertical height is designated as Δ B _H, more than displacement on three directions can try to achieve with following formula:

$\mathrm{\&Delta;}{B}_N=\frac{\mathrm{<figure-callout\; id="1"\; label="l"\; filenames="HDA0000147402580000011.png,HDA0000147402580000021.png"\; state="\{\{state\}\}">l</figure-callout>}}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_E\right)}}\&CenterDot;\tan \left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)---\left(1\right)$

$\mathrm{\&Delta;}{B}_E=\frac{\mathrm{<figure-callout\; id="1"\; label="l"\; filenames="HDA0000147402580000011.png,HDA0000147402580000021.png"\; state="\{\{state\}\}">l</figure-callout>}}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_E\right)}}\&CenterDot;\tan \left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)---\left(2\right)$

$\mathrm{\&Delta;}{B}_H=l[1-\frac{1}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_E\right)}}]---\left(3\right)$

L is that the bar of measuring unit is long

2. the displacement of continuous multi-stage measuring unit is calculated:

Suppose that whole survey line is made up of N measuring unit, the end points of i unit is respectively i _A, i _B, the inclination angle is changed to Δ θ _IN, Δ θ _IE, the displacement of A end is a Δ _IAN, Δ _IAEAnd Δ _IAH, then the B displacement of ordering is:

${\mathrm{\&Delta;}}_{\mathrm{iBN}}={\mathrm{\&Delta;}}_{\mathrm{iAN}}+\frac{\mathrm{<figure-callout\; id="1"\; label="l"\; filenames="HDA0000147402580000011.png,HDA0000147402580000021.png"\; state="\{\{state\}\}">l</figure-callout>}}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_E\right)}}\&CenterDot;\tan \left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)---\left(4\right)$

${\mathrm{\&Delta;}}_{\mathrm{iBE}}={\mathrm{\&Delta;}}_{\mathrm{iAE}}+\frac{\mathrm{<figure-callout\; id="1"\; label="l"\; filenames="HDA0000147402580000011.png,HDA0000147402580000021.png"\; state="\{\{state\}\}">l</figure-callout>}}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_E\right)}}\&CenterDot;\tan \left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_E\right)---\left(5\right)$

${\mathrm{\&Delta;}}_{\mathrm{iBH}}={\mathrm{\&Delta;}}_{\mathrm{iAH}}+l[1-\frac{1}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_N\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_E\right)}}]---\left(6\right)$

3. along the accumulation displacement derivation formula of journey each point:

Make the displacement of starting point 0:

Δ _0N＝0 (7)

Δ _0E＝0 (8)

Δ _0H＝0 (9)

Then the displacement of i section B point is:

${\mathrm{\&Delta;}}_{\mathrm{iBN}}=\underset{i=0}{\overset{i=N-1}{\mathrm{\&Sigma;}}}[{\mathrm{\&Delta;}}_{\mathrm{iBN}}+\frac{l_i}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iN}}\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iE}}\right)}}\&CenterDot;\tan \left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iN}}\right)](i=\mathrm{0,1,2}\mathrm{\&Lambda;N}-1)---\left(10\right)$

${\mathrm{\&Delta;}}_{\mathrm{iBE}}=\underset{i=0}{\overset{i=N-1}{\mathrm{\&Sigma;}}}[{\mathrm{\&Delta;}}_{\mathrm{iBE}}+\frac{l_i}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iN}}\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iE}}\right)}}\&CenterDot;\tan \left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iE}}\right)](i=\mathrm{0,1,2}\mathrm{\&Lambda;N}-1)---\left(11\right)$

${\mathrm{\&Delta;}}_{\mathrm{iBH}}=\underset{i=0}{\overset{i=N-1}{\mathrm{\&Sigma;}}}[{\mathrm{\&Delta;}}_{\mathrm{iBH}}+l_i(1-\frac{1}{\sqrt{1+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iN}}\right)+{\tan }^2\left(\mathrm{\&Delta;}{\mathrm{\&theta;}}_{\mathrm{iE}}\right)}})](i=\mathrm{0,1,2}\mathrm{\&Lambda;N}-1)---\left(12\right)$

Application examples 1

A side slope that provides like Fig. 6; Pre-buried inside anchor cable is along journey continuous dislocation measuring instrument, and the distortion of the destruction of side slope can be monitored the distortion of side slope anchor cable in real time shown in the figure red line; Destruction to side slope is played forewarning function; At this moment A and B end all is deformed to A ' and B ', record the change in displacement of A end after, the displacement that B holds can be calculated with reference to formula (10)～(12).

The above; It only is the preferred embodiment of the utility model; Be not that the utility model is done any pro forma restriction; Every technical spirit according to the utility model all still belongs to the protection domain of the utility model technical scheme to any simple modification, equivalent variations and modification that above embodiment did.

Claims (6)

1. anchor cable is along journey continuous dislocation measuring instrument; Comprise measurement mechanism (10), data transmission device, data analysis set-up (12); It is characterized in that: measurement mechanism is made up of measuring unit (4); Measuring unit comprises shell pvc pipe (1), MEMS acceleration transducer (2) and data line (5), and MEMS acceleration transducer (2) is in the shell pvc pipe and be connected with data line (5); Data transmission device comprises data acquisition unit (13), wireless launcher (8), wireless receiver (11), data-carrier store (14) and solar cell (9); Data acquisition unit (13) links to each other with measurement mechanism (10), wireless launcher (8), solar cell (9) respectively; Data-carrier store (14) links to each other with data analysis set-up (12), wireless receiver (11), solar cell (9) respectively; Through wireless launcher (8) and wireless receiver (11) transceive data, data acquisition unit (13) links to each other with data analysis set-up (12).

2. anchor cable according to claim 1 is characterized in that along journey continuous dislocation measuring instrument: the quantity of measuring unit (4) is a plurality of, MEMS acceleration transducer (2) series connection in each measuring unit (4), and through steel wire (3) and data line (5) connection.

3. anchor cable according to claim 1 and 2 is characterized in that along journey continuous dislocation measuring instrument: the quantity of the MEMS acceleration transducer in each measuring unit is 2.

4. anchor cable according to claim 1 and 2 is characterized in that along journey continuous dislocation measuring instrument: MEMS acceleration transducer (2) is at the center of shell pvc pipe (1).

5. anchor cable according to claim 1 is characterized in that along journey continuous dislocation measuring instrument: be provided with fiber protective sleeve (6) and flexible high molecular material layer (7) in the inside of shell pvc pipe (1).

6. anchor cable according to claim 1 is characterized in that along journey continuous dislocation measuring instrument: data analysis set-up (12) comprises server.

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