Showing posts with label inertial sensor. Show all posts
Showing posts with label inertial sensor. Show all posts

Monday, May 31, 2021

How to use IMU (inertial measurement unit )in pipeline 3D attitude measuring ?

Inertial navigation is an inertial measurement unit (IMU) composed of a gyroscope and an acceleration sensor to measure angular velocity and acceleration information of the carrier.Based on the inertial measurement principle, the pipeline attitude measuring instrument introduced in this paper measures its own three-axis attitude Angle or angular velocity, current acceleration, etc., and analyzes and calculates these attitude quantities, so as to obtain the three-dimensional attitude of the pipeline.

.Let's take a look a measuring instrument based on inertial measurement sensor technology -- pipeline three-dimensional attitude measuring instrument.

As a common instrument for measuring the precise attitude (trajectory) of underground pipelines, the pipeline attitude measuring instrument is a kind of three-dimensional precise attitude measuring instrument based on MEMS inertial measurement unit.This kind of product has internal integration of inertial guided measurement unit, lithium battery, DSP and mass storage unit, which can complete the collection without external auxiliary equipment. It adopts all-metal sealing structure and adaptive shrinkage guide device, which can adapt to the traction and travel of various inner diameter pipelines. It is shockproof and always keeps the measuring unit on the center line of the pipeline.It is mainly applied to the completion measurement of pipe jacking construction in trenchless industries of underground pipelines such as electric power, gas and water.

In the process of use, the pipeline attitude measuring instrument can measure its own three-axis attitude Angle or angular velocity, current acceleration and travel distance through the inertial measurement sensor device. These attitude values are analyzed and calculated by the integral algorithm, so as to obtain the three-dimensional attitude of the pipeline.In complex urban environment, this kind of instrument can accurately measure the three-dimensional data of underground pipeline, which is especially suitable for the measurement and positioning of pipeline completion.

At present, the existing pipe network and well chamber detection technology includes ground detection and underground detection. Ground detection is mainly carried out by radar, infrared ray and ultrasonic methods for line finding and flaw detection.Although the detection is conducted directly on the surface, the detection efficiency is low and the detection accuracy cannot be guaranteed. At the same time, there are certain requirements for the technical level of the detection personnel and the cost of the detection equipment is also relatively expensive.Underground detection technology consists of laser radar, closed-circuit television, downhole robot: although laser radar theory can more accurate detection of pipe network, but to the well chamber test is difficult, expensive equipment at the same time, inconvenience, for operating and testing personnel requirements are high, the result is not intuitive, practicality is not high.



For trenchless pipeline of accurate location information in pipeline construction, the scientific use of underground space, the maximum to avoid the line cut, eliminate the potential accidents, by adopting pipeline three-dimensional attitude measuring instrument, to the trenchless pipeline in pipeline construction to carry on the accurate measurement and positioning, so as to solve the above other detection means can't solve the practical problems.

It should be noted that, in practical application, because the pipeline 3D attitude measuring instrument is based on the principle of accurately measuring its own motion trajectory and obtaining the central coordinate sequence of the measured pipeline, its measurement accuracy is not only limited by the built-in core inertial sensor measurement unit, but also closely related to the structural stability of the instrument during operation.Therefore, keeping the structure of the measuring pipe stable is also one of the prerequisites for accurate data measurement by the 3D attitude measuring instrument .




How to choose an electronic compass ?

There are a lot of people in the choice of electronic compass do not know how to choose, sometimes because did not consider the following content, and choose the wrong electronic compass, resulting in a waste of time and money, let us to see some tips when choose an electronic compass. 

First, let's take a look at what an electronic compass, also known as a digital compass, is a way of locating the North Pole using the geomagnetic field.

Secondly, as an important navigation and orientation tool, electronic compass is increasingly used in navigation and orientation systems.Most current navigation systems use an electronic compass to indicate direction.The electronic compass can accurately output Azimuth, pitch, Roll and other parameters by calculating the earth's magnetic field and gravitational field.

Known the basic concept of the electronic compass, now let's take a look at the electronic compass types on the market, manufacturers, many models, in the face of these we may look confused, so how to distinguish the performance of the electronic compass, how to choose a suitable for your application of the electronic compass?What's the difference between a good compass and a bad compass?

The main difference between electronic compasses is the difference in accuracy, namely the accuracy of heading, pitch and roll, and especially the accuracy of heading.The heading is defined as the Angle between the projection of the compass's axis on the horizontal plane and the north direction, the pitch is defined as the Angle between the compass's axis and the ground plane, and the roll is defined as the Angle at which the compass rotates about its axis.As shown in the figure below

According to the above definition, if the compass changes only in pitch, then its output azimuth and roll Angle should remain the same.In the same way, if a compass rolls about itself, that is, on its axis, the azimuth and pitch angles of its output should remain the same.In the use of compass, such as used in vehicles, antenna orientation and surface buoys and many other occasions, the carrier will often tilt back and forth, when used in petroleum, geological logging, often rotation, so most applications require compass to meet the requirements of tilt and roll orientation will not change.
Another requirement for compass accuracy is that the output of the compass should be 0 degrees if the current carrier is pointing north, and 90 degrees if the carrier is pointing east. The measured value and the true value should match exactly within the margin of error

For petroleum, geological, and coal logging, the orientation and inclination of the product should not change as the logging instrument rotates downhole, which is important for logging applications.
Another rule when choosing a compass is whether it is resistant to harsh conditions.A natural disadvantage of compasses is that they become less accurate in environments with magnetic interference.Compasses use the direction of the Earth's magnetic field to determine orientation. If the Earth's magnetic field is disturbed or distorted, the accuracy of orientation measurement will be reduced.Iron materials, batteries, motors, high currents, and so on can interfere with the geomagnetic field, and the closer these materials are to the compass, the worse the interference is.So if you want the compass to be accurate, you have to stay away from the source of the interference, but in many cases this is not possible.So the only way to solve this problem is to do magnetic calibration.In the process of magnetic calibration, the compass rotates with the measured object (i.e., the interference source) in a certain way and learns the surrounding magnetic environment to distinguish which is magnetic interference and which is geomagnetic field. Through this learning, the interference is eliminated and the high-precision azimuth output is obtained.




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