RU190429U1 - DEVICE FOR MEASURING AZIMUTA - Google Patents

Abstract

Use: measurement of magnetic azimuth of moving objects. Purpose: expansion of functionality, improvement of measurement accuracy and manufacturability of the device design. The essence of the utility model: the device contains three accelerometers 1, 2, 3 and three magnetometric sensors 4, 5, 6, all sensors are installed in a cylindrical housing 7 and placed in such a way that each accelerometer and each magnetometric sensor can be combined with adjacent sensors of the same type displacement along the axis of the housing and rotation around this axis by ± 120 ° or only by rotation around the axis of the housing by ± 120 °, while reducing accelerometers and magnetometric measurements to reduce the effect of accelerometers on the operation of magnetometric sensors Sky sensors can be deployed relative to the axis of the housing at different angles. 4 il.

Description

The utility model relates to the field of controlling the orientation of moving objects and can be used in the construction of inclinometers, compasses and magnetometers for various purposes.

A well-known sensor for measuring the azimuth in a well, containing three ferrosonde, located in an annular body in such a way that their sensitivity axes form 120 ° angles between themselves and lie in parallel planes perpendicular to the axis of the body, and the centers of the fluxglobes are on the axis of the body. 605950, E21B 47/022, BI No. 17, 1978].

The disadvantage of the sensor is that the location of the axes of sensitivity of the flux-probes in parallel planes allows you to measure only the projection of the geomagnetic field vector on a plane parallel to the planes of the axes of sensitivity of the flux-probes, and not the full vector. In addition, the disadvantage of the sensor is the complexity of the design, due to the use of three flux-probes, while for measuring the azimuth in this case it is sufficient to use only two flux-probes, thereby simplifying the design of the sensor and the flux-signal conversion circuit.

A magnetic azimuth sensor is known that includes three core ferrosonde mounted in a cylindrical body, the sensitivity axes of which form equal angles with the longitudinal axis of the body, the values of which are less than 57.36 °, and the angles between the projections of the sensitivity axes of the magnetic fluxes on the plane of the cross section of the body are 120 ° [The patent of the Russian Federation No. 201464, Е21В 47/02, BI No. 16, 1994].

Compared with the previous analogue, this sensor provides a measurement of the full vector of the geomagnetic field, but has large overall dimensions, since to exclude mutual influence, the flux-probes are arranged at a certain distance from each other, which increases the length of the sensor body. In addition, the disadvantage of the sensor is that by itself it cannot measure the magnetic azimuth, since this requires data on its orientation relative to the vertical of the terrain, which can only be obtained from an additional sensor.

Also known is a magnetometric sensor containing three identical fluxgates fixed in a cylindrical housing, the sensitivity axes of which form the same angles with the longitudinal axis of the housing, and the angles between the projections of the sensitivity axes of the fluxing probes on the plane of the cross section of the housing are 120 °. In addition, each of the flux-probes can be combined with the neighboring flux-probes by turning around the longitudinal axis of the body through an angle of ± 120 ° [RF Patent №2235200, EV 47/02, BI No. 24, 2004].

Compared with the known devices made on the basis of magnetic primary transducers and measuring the full vector of the geomagnetic field, this sensor has the smallest overall dimensions, which allows you to create on its basis miniature magnetometric devices.

The disadvantage of the sensor is that it can be used to determine the magnetic azimuth only complete with additional sensors that determine the position of the moving object relative to the vertical of the terrain. By itself, a magnetometer sensor can measure only the coordinates of the geomagnetic field vector in the coordinate system associated with the sensor body, and the length of the geomagnetic field vector has limited functionality.

The closest in technical essence to the claimed device for measuring azimuth is a gravimetric sensor, adopted as a prototype and containing three identical accelerometers fixed in a cylindrical case, the sensitivity axes of which form the same angles with the longitudinal axis of the case, and each of the accelerometers can be combined with adjacent accelerometers by moving along the axis of the body and turning around this axis by ± 120 ° [Utility Model Patent No. 37523, Е21В 47/02, BI No. 12, 2004].

Due to the azimuth of a moving object, it is measured from the magnetic or geographical meridians when it rotates around a vertical axis, which represents the gravitational vertical of the area, devices for measuring azimuth always include gravimetric sensors that track the position of the moving object relative to the vertical. Therefore, it is the gravimetric sensor, as the base sensor of any device for measuring azimuth, was chosen as the prototype of the proposed technical solution.

The disadvantage of this gravimetric sensor is that, like the known magnetic field sensors, it allows you to determine the orientation of a moving object only with respect to one vector of the geophysical field, in this case the vector of the gravitational field, while measuring two vectors is required to determine the spatial orientation of the object .

When placing accelerometers, this sensor uses the same approach as when placing magnetometric sensors in known devices. However, it differs significantly from them in its physical essence and functional purpose, which consist in measuring the gravitational vector, not the geomagnetic field.

The utility model solves the problem of expanding the functionality of a gravimetric sensor and at the same time increasing the measurement accuracy and the manufacturability of its design.

The technical result from the use of the claimed device for measuring azimuth compared to similar devices containing three-component gravimetric and magnetometric sensors consists in a relative decrease in the size of the device due to the use of sensors with the smallest dimensions and an increase in the measurement accuracy due to the relative rotation of the sensors around the axis of the body, allowing reduce the influence of gravimetric sensors on the operation of magnetometric sensors.

The solution of these problems is achieved by the fact that the device for measuring azimuth, containing three identical accelerometers, in which the sensitivity axes form the same angles with the longitudinal axis of the cylindrical body, the values of which are within [Δ ₁ , 90 ° - δ ₁ ] and [90 ° + δ ₁ , 180 ° - Δ ₁ ], where Δ ₁ , δ ₁ are the angles causing the permissible error of measurement of the gravitational field vector, and the angles between the projections of the sensitivity axes onto the cross section plane of the body are 120 °, three identical magnetometric sensors are introduced ka (ferrozond), in which the axes of sensitivity form the same angles with the axis of the body, the values of which lie within [Δ ₂ , 90 ° -δ ₂ ] and [90 ° + δ ₂ , 180 ° -Δ ₂ ], where Δ ₂ , δ ₂ - angles that determine the permissible error of measurement of the geomagnetic field vector, the angles between the projections of the sensitivity axes on the plane of the cross section of the body are 120 ° and each of the magnetometric sensors can be combined with adjacent magnetometric sensors by turning around the axis of the body by ± 120 °, with In this case, each accelerometer can also It is combined with adjacent accelerometers by rotating around the axis of the body by ± 120 °, while accelerometers and magnetometric sensors can have different angles of rotation relative to the axis of the body.

The proposed device combines a three-component gravimetric and magnetometric sensors. Accelerometers are used as gravimetric sensors, and flux-probes or magnetoresistive sensors can be used as magnetometric sensors. Due to its location in the housing, both gravimetric and magnetometric sensors have the smallest possible overall dimensions, in connection with which this device has the smallest dimensions among similar devices with the same set of sensors.

By combining the functions of the sensors included in it, the device acquires the necessary functions missing from the nearest analogues and provides full control over the orientation of moving objects relative to the surface of the Earth.

The essential difference of the proposed device consists in the relative reversal of the groups of gravimetric and magnetometric sensors around the longitudinal axis of the housing. Due to this, without increasing the length of the body, the magnetic influence of the structures of gravimetric sensors on the operation of the magnetometric sensors is reduced and the accuracy of measurements of the geomagnetic field vector accordingly increases. In known devices, this problem is solved only by separating the gravimetric and magnetometric sensors along the axis of the housing for the required distance and leads to an increase in the overall dimensions of the devices. In addition, the relative rotation of the sensors in some cases helps to optimize the design of the device.

In the proposed device, a pair of sensors, including one accelerometer and one magnetometric sensor, can be located on separate planes parallel to the axis of the housing. This increases the manufacturability of the device due to the same processing in the manufacture of three identical surfaces rotated relative to each other by 120 °, and the relative rotation of gravimetric and magnetometric sensors around the axis of the housing is achieved by simply displacing each pair of sensors in these planes in directions perpendicular to the axis of the housing. The latter technique is a new and not obvious solution to the problem of increasing accuracy due to the relative rotation of the sensors.

In addition, the sensors in the proposed device can be located so that the geometric centers of their buildings will be in the same plane and each of the accelerometers will be located between adjacent magnetometric sensors. In this case, the proposed device in comparison with all known similar devices will have the smallest overall dimension along the axis of the housing.

FIG. 1-3 shows the construction of the device for measuring azimuth with various types of sensor arrangements, and in FIG. 4 is a graph of the dependence of the coefficient characterizing the measurement error of the vectors of geophysical fields on the angles of inclination of the sensitivity axes of the sensors to the axis of the hull.

The device for measuring azimuth contains a three-component gravimetric sensor, which includes three accelerometers 1, 2, 3, and a three-component magnetometric sensor, consisting of three one-component magnetometric sensors 4, 5, 6, which use ferrosonds or magnetoresistive sensors. All sensors are placed in a cylindrical housing 7 (Fig. 1).

In this device, reducing the effect of accelerometers on the operation of magnetometric sensors is achieved not only by removing the latter from the accelerometers at a distance L, but also by their relative rotation around the axis of the body, since The relative rotation of the sensors at a constant value of L makes it possible to further increase the distances between the accelerometers and the corresponding magnetometric sensors, thereby further reducing the effect of the accelerometers and increasing the measurement accuracy.

The axes of sensitivity of accelerometers form the same angles γ ₁ with the longitudinal axis of the case, and the axes of sensitivity of the magnetometer sensors also form the same angles γ ₂ . In addition, each sensor can be combined with the corresponding neighboring sensors of the same type by turning around the axis of the housing 7 by ± 120 °.

The values of the angles γ ₁ and γ ₂ are selected within [Δ _i , 90 ° –δ _i ] and [90 ° + δ _i , 180 ° –Δ _i ], where i = 1 for accelerometers, respectively, i = 2 for magnetometric sensors, a Δ _i , δ _i - angles that determine the permissible errors of measurement of the vectors of the corresponding physical fields.

The orientation of the sensitivity axes of the same type sensors in the device is described by a common operator.

(i=1), и осей чувствительности магнитометрических датчиков

(i=2) представляется операторамиwhere β _i is the angle of relative rotation of the sensors around the axis of the housing in the coordinate system associated with the housing of the device (Fig. 1). In this regard, the orientation of the axes of sensitivity of accelerometers

(i = 1), and the axes of sensitivity of magnetometric sensors

(i = 2) represented by operators

In this case, the vectors of the signals of accelerometers and magnetometric sensors are determined by the equations

- векторы сигналов датчиков, u₁ … u₆ - значения сигналов датчиков без учета разброса значений их коэффициентов преобразования,

- единичные векторы гравитационного поля и геомагнитного поля в указанной системе координат, связанной с корпусом устройства.u _G = Ng, u _M = Mh, (3) where

- vectors of sensor signals, u ₁ ... u ₆ - values of sensor signals without taking into account the spread of the values of their conversion factors,

- unit vectors of the gravitational field and geomagnetic field in the specified coordinate system associated with the device body.

During operation of the device, the current values of the sensor signals are measured, which, by means of transformation using the operators N ^-1 , M ^-1 having matrices inverse to the matrices (2), allow to determine the unit vectors of the measured physical fields

The coordinates of these vectors are used further to calculate the azimuth of the moving object.

If the direction of motion of the object on which the device for measuring the azimuth is installed, coincides with the Z axis of the adopted coordinate system (Fig. 1), then the magnetic azimuth of the object is calculated by the formula

In order to improve manufacturability and simplify the design of the device, each pair of sensors, including one accelerometer and one magnetometric sensor, can be placed on a separate plane, for example, on a separate printed circuit board. In this case, the device will include three identical boards, each of which can be combined with adjacent boards by turning around the axis of the housing 7 by ± 120 °, and the relative rotation of the sensors around the axis of the housing will be ensured by their displacements on the boards in the L1 and L2 directions, perpendicular to the axis of the housing (Fig. 2).

Accelerometers and magnetometric sensors can be located in the same cross-sectional plane of the device body 7 (Fig. 3). In this case, the effect of accelerometers on the operation of magnetometric sensors is eliminated both by their relative rotation around the axis of the housing and by increasing the diameter of the housing. It is obvious that the angle of rotation, which ensures the greatest distance of each of the magnetometric sensors from the nearest accelerometers, is approximately 60 °.

If the values of the tilt angles of the sensitivity axes of the sensors γ _i approach 0 °, 90 ° and 180 °, then the errors in measuring the directions of the vectors of geophysical fields increase significantly. Accordingly, the error in measuring the azimuth increases. The maximum values of the angles between the true and measured values of the vectors of geophysical fields Δϕ _i depending on the maximum errors of setting the tilt angles of the sensitivity axes of the sensors Δγ _i can be estimated using the formula

Where

A graph of the dependence of the coefficient K on the magnitude of the angles of inclination of the axes of sensitivity of the sensors with respect to the longitudinal axis of the device housing is shown in FIG. 4. It can quickly find the values of the coefficient for given values of angles Δ _i and δ _i and to determine whether the selected values provide angles γ _i at a given their installation error Δγ _i vectors necessary measurement error Δφ _i.

For example, if the angles of inclination of the sensitivity axes of the magnetometer sensor to the axis of the body are γ ₂ = 30 ° and are set with an accuracy of Δγ ₂ = ± 1.0 °, then K (γ ₂ ) = 2.72 and the measurement error of the direction of the magnetic field vector is Δϕ ₂ = ± 2.7 °.

On the other hand, if the sensitivity axes of the sensors are set with an error of Δγ _i = ± 0.2 ° and the accuracy of measuring the directions of vectors is limited to Δϕ _i = ± 1.0 °, then K = 5 and γ _i should have values corresponding to K≤5 conditions and δ _i ≥16 ° and δ _i ≥22 ° (Fig. 4). Therefore, the angles of inclination of these axes can be in the range of γ _i = [16 °; 68 °] or γ _i = [112 °; 164 °].

The minimum value of the coefficient K, equal to about 1.95, is achieved with the orthogonal arrangement of the sensitivity axes of the sensors, when the angles of inclination of their axes to the axis of the body are 54.73 ° or 125.27 °.

The proposed azimuth sensor is implemented on the basis of MEMS accelerometers and magnetoresistive sensors in the SKB Katav-Ivanovo instrument-making plant with the aim of using it in underwater navigation systems.

Claims (1)

A device for measuring azimuth, containing three identical accelerometers, in which the sensitivity axes form the same angles with the longitudinal axis of the cylindrical body, the values of which are within [Δ ₁ , 90 ° - δ ₁ ] and [90 ° + δ ₁ , 180 ° - Δ ₁ ], where Δ ₁ , δ ₁ are the angles causing the permissible error of measurement of the gravitational field vector, and the angles between the projections of the sensitivity axes on the cross-sectional plane of the body are 120 °, characterized by the fact that three identical magnetometric sensors are inserted in which the axes h vstvitelnosti form with the housing axis and equal angles, the values of which lie within [Δ _2, 90 ° -δ _2] and [90 ° + δ _2, 180 ° -Δ _2] where Δ _2, δ ₂ - angles defining permissible The measurement error of the geomagnetic field vector, the angles between the projections of the sensitivity axes on the plane of the cross section of the body are 120 °, and each of the magnetometric sensors can be combined with the adjacent magnetometric sensors by rotating around the axis of the body by ± 120 °, while each of the accelerometers can also be combined with neighboring axel Ometers can be rotated around the axis of the housing by ± 120 °, while accelerometers and magnetometric sensors can have different angles of rotation relative to the axis of the housing.

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