阅读说明：本技术 一种超导重力梯度仪共模抑制调平结构 (Common mode rejection leveling structure of superconducting gravity gradiometer ) 是由 陈培 茆雪健 贾振俊 于 2019-10-25 设计创作，主要内容包括：本发明公开了一种通过对超导重力梯度仪内部结构的配对调整达到共模信号不输出的调平结构及相应的调平流程。基于超导重力梯度仪中悬浮质量块运动特性与姿态耦合的特性,该调平结构在保留原有超导重力梯度仪基本结构的基础上,延伸悬浮质量块侧翼,并在侧翼位置安装两翼线圈组,通过两翼线圈组中的不同大小的电流组合控制悬浮质量块的姿态,补偿加工、装配精度不足带来的偏差。调平过程主要为按照一定方式调整两翼线圈中的电流,分别实现在低频下共模信息不输出和在高频下共模信息不输出,迭代操作,实现全宽带内共模信号不输出调平。(The invention discloses a leveling structure and a corresponding leveling process for achieving the purpose that a common-mode signal is not output through matching adjustment of an internal structure of a superconducting gravity gradiometer. Based on the characteristic of coupling motion characteristic and attitude of a suspended mass block in a superconducting gravity gradiometer, the leveling structure extends the lateral wing of the suspended mass block on the basis of keeping the basic structure of the original superconducting gravity gradiometer, two wing coil groups are installed at the position of the lateral wing, the attitude of the suspended mass block is controlled through the combination of currents with different sizes in the two wing coil groups, and the deviation caused by insufficient processing and assembling precision is compensated. The leveling process mainly comprises the steps of adjusting currents in the coils of the two wings according to a certain mode, respectively realizing the non-output of common mode information under low frequency and the non-output of common mode information under high frequency, carrying out iterative operation, and realizing the non-output leveling of common mode signals in a full-width band.)

1. The utility model provides a through the gesture of suspension quality piece in the control superconductive gravity gradiometer, reach the two wing coil assembly structures of common mode rejection leveling which characterized in that: two sides of the suspension mass block extend out of the two-wing structure to provide space for the two-wing coil group; the coils in the two wing coil groups are arranged at the top points of the cuboid in space, and control force and control moment are generated through different currents in the coils, so that common mode rejection leveling is realized.

2. The suspended mass block structure with wing-like structures extending from two sides according to claim 1, wherein: the center is a cylindrical niobium pipe, the upper and lower disc structures and the two wing structures are sleeved on the niobium pipe in a coaxial matching mode and fixed by low-temperature glue; the surfaces of all the parts are plated with insulating paint to realize mutual insulation; high-precision leveling bolts are installed at two ends of the two-wing structure, and the mass center position of the two-wing structure is adjusted through the screwed-in depth of the fine adjustment bolts.

3. The two-limb coil assembly structure of claim 1, wherein: the two-wing coil group is composed of 8 planar coils, the planar coils are the same in size and parallel to each other, the centers of the planar coils are arranged at the top of a cuboid in the space, and two planar coils corresponding to the diagonal lines of the cuboid are in the same current loop.

4. A common mode rejection leveling mode of a superconducting gravity gradiometer based on a two-wing coil group structure is characterized in that: two attitude degrees of freedom of the suspension mass block can be controlled by passing current into the two wing coil groups, full-width band leveling without outputting common mode signals can be achieved by two steps, the first step is that the Y-direction attitude of the upper mass block and the lower mass block are adjusted at the same time at a low frequency to achieve low-frequency common mode signal non-output, the second step is that the Z-direction attitude of the upper mass block and the lower mass block are adjusted at the same time at a high frequency to achieve high-frequency common mode signal non-output, the first step and the second step are operated repeatedly until the X-direction attitude and the Y-direction attitude of the mass blocks are not leveled, and full-width band leveling.

Technical Field

The invention relates to a leveling structure for achieving common-mode signal non-output through matching adjustment of an internal structure of a superconducting gravity gradiometer, and belongs to the field of electrical engineering.

Background

In the gravity field, after a zero potential point is selected, each point has a determined gravitational potential, the gravitational potential is a scalar quantity, the variation gradient of the gravitational potential along each direction is the gravitational acceleration along the direction, and further, the variation gradient of the gravitational acceleration along each direction is the gravitational gradient. Describing the gravity gradient mathematically, and setting the gravity potential of each point in the gravity field as phi (x, y, z), the gravity acceleration along the x, y, z direction isFurther derive a gravity gradient expression:

the superconductive gravity gradiometer is a high-precision instrument for measuring gravity gradient, is usually arranged on airplanes and ships, has important significance for geoscience, geology, space science and high-precision inertial guidance, has high application value in the field of geological resource exploration due to the high precision and high sensitivity of the gravity gradiometer, and is an important means for resource exploration such as basic geological investigation, basic geological research, oil and gas mineral deposit and the like. The gravity acceleration information is obtained by directly measuring the gravity acceleration of a part of gravity measuring instruments, and the mounting platform of the gravity measuring instruments is often not absolutely static, so the measured gravity acceleration contains a part of inertial acceleration, the accurate inertial acceleration information must be known to obtain the accurate gravity acceleration information, and a large error is often caused by the process, particularly the gravity field modeling precision requirement of gravity matching navigation is met, and the measurement error is obviously unacceptable. Two paired accelerometers are arranged in the superconducting gravity gradiometer, and the inertial acceleration caused by the motion of the mounting platform is eliminated in a differential mode, wherein the inertial acceleration is common-mode acceleration, and the common-mode acceleration is not output, namely common-mode inhibition. Under ideal conditions, the upper accelerometer and the lower accelerometer are perfectly matched, so that common mode rejection at any frequency can be realized, in actual processing and manufacturing, due to processing errors, material defects and the like, ideal accelerometer matching cannot be realized, and at the moment, the common mode rejection in an expected measurement frequency bandwidth needs to be realized through structural member adjustment, electrical component matching and the like.

The existing common mode suppression leveling means is mainly derived from a leveling thought given by a research team of a superconducting gravity gradiometer of the university of Maryland in America aiming at a gravity gradiometer designed by the research team of the superconducting gravity gradiometer, a leveling thought and a criterion for judging the leveling effect are also given by a research team of related superconducting gravity gradiometers domestically, three existing leveling thoughts and corresponding superconducting gravity gradiometer structures are discussed briefly below and are respectively marked as A, B, C, wherein A and B are derived from the research team of the physical system of the university of Maryland in America, C is derived from a research team consisting of a domestic Hubei gravitational force and quantum measurement laboratory and the science and technology university in Wuhan Hua, and the structural schematic diagrams of the three types refer to.

Referring to FIG. 1A type schematic diagram of the basic structure of a superconductive gravity gradiometer, according to the subscripts of various parameters and the circuit structure, the whole structure forms a set of difference system I_d(t) differential current corresponds to gravity gradient information, I in the whole system_d(t) and m₁、m₂The motion existence transmission relation of (1) is as follows:

wherein g is_d(omega) differential mode acceleration corresponding to gravity gradient, g_c(omega) is that the common mode acceleration corresponds to the platform movement, and the target requires that the system only obtains the differential mode acceleration, so thatCorrespond to and are adhered to

To realize the balance bar of the formula (3)In the first step, at ω > ω_1c，ω_2cIn the case of (1), regulating₁And I₂So that the output signal does not contain common mode information, in this case

In the second step, in omega < omega_1c，ω_2cIn the case of (1), adjust i₁And i₂So that the output signal does not contain common mode information, in this case

The first step and the second step are repeatedly operated, so that the formulas (4) and (5) are simultaneously satisfied, and it can be seen that the formula (3) is satisfied no matter what value omega is taken, namely, the leveling within a certain frequency bandwidth is realized.

Similar to the leveling process of the A type of the basic structure of the superconducting gravity gradiometer, the leveling idea of the B type is mainly as follows: under the existing high-precision processing condition, the internal structure of the superconducting gravity gradiometer is close to common-mode rejection leveling, and a tiny compensation quantity is needed to realizeDue to mutual coupling of the parameters, when the frequency changes

The conditions required to be met can be changed, in addition, the repeated operation leveling mode in the type A is very complicated and can not ensure the leveling effect within a certain number of times, and additional tiny compensation current I is introduced into the type B_B1And I_B2Hold of I_S1＝I_S2Adjustment of I_B1And I_B2Can be realized at any frequencyAll the above holds, namely common mode rejection leveling in a certain frequency bandwidth is realized.

Type C is a leveling scheme provided by research team of superconducting gravity gradiometer of Huazhong university of science and technology, the leveling scheme is essentially consistent with type B, and I is_LCurrent loop and I_BThe current loops are combined into a current loop which is more simplified than the type B, and the current loop passes through the R_aAdjustment I_L1-I_L2The common mode rejection leveling within a certain frequency bandwidth can be realized by performing small compensation.

The above 3 common mode rejection leveling modes are all leveling from inside of the circuit structure, leveling is realized by changing initial current parameters and adjusting internal energy distribution, however, within a certain frequency bandwidth, due to reasons such as machining precision, leveling conditions cannot avoid drifting along with frequency changes, so we think of a 'clean' leveling mode which adjusts from outside without changing internal initial current parameters and energy distribution.

Disclosure of Invention

The invention aims to adjust the internal structure pairing of the superconducting gravity gradiometer through an additional structure to realize common mode rejection. The leveling structure does not change internal initial current and energy distribution, is clean and efficient, and is suitable for various superconductive gravity gradiometers.

Under ideal processing conditions, the internal structures of the superconducting gravity gradiometers should be completely matched, for example, the A-type superconducting gravity gradiometer basic structure shown in FIG. 1 should be omega under the condition of complete matching_1c＝ω_2c、L_1a＝L_2a、L_1b＝L_2b、L_1p＝L_2pAt this time, only initial current-I 'needs to be set'₁＝I′₂The formula (3) can be satisfied, and the common mode rejection leveling in a certain frequency bandwidth is realized. Under actual processing conditions, L is caused mainly by manufacturing deviation of the planar coil and the fact that the mass distribution of the suspended mass block is not strictly centrosymmetric_1a≠L_2a、L_1b≠L_2b、L_1p≠L_2pThe existing leveling mode does not change the inductance of each coil, the deviation of the unbalance is compensated by setting the initial current or increasing a small current loop, however, the required compensation is changed along with the change of the frequency, and the deviation is also compensatedBrings great difficulty to leveling in a certain broadband.

According to the invention, the two-wing leveling coils are introduced by extending the suspension mass block structure, the two-wing coils generate a leveling magnetic field orthogonal to the measurement direction, and the attitude of the suspension mass block is finely adjusted by controlling the current in the two-wing coil group, so that the inductance of each coil in the measurement direction is finely adjusted, and omega is enabled to be omega_1c＝ω_2c、L_1p＝L_2pSo that the leveling condition does not drift with frequency and leveling only needs to be maintained at-I'₁＝I′₂By adjusting the common-mode transfer function at two frequenciesCan be realized in a certain frequency bandwidthThe leveling condition is prevented from drifting along with the frequency, and the method is simple and efficient.

Drawings

FIG. 1 is a schematic diagram of the basic structure of a superconductive gravity gradiometer

FIG. 2 is B-type schematic diagram of the basic structure of a superconductive gravity gradiometer

FIG. 3 is a schematic view of the basic structure of a superconductive gravity gradiometer in type C

Fig. 4 is a schematic diagram of an extended improved suspended mass block configuration of the present invention.

FIG. 5 is a three-dimensional schematic diagram of the overall structure of the single-axis gravity gradiometer.

Fig. 6 is a schematic diagram of the distribution of the two-wing suspension coil of the mass block.

Fig. 7 is a schematic diagram of the electrical connections of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 4 shows an extended suspended mass block structure with two wings, the whole mass block is composed of 4 structures, and a common suspended mass block is composed of only a No. 2 structure and a No. 3 structure, namely, the suspended mass block has no two-wing structure. The surfaces of the No. 2, No. 3 and No. 4 structures are covered with insulating paint, so that the superconducting structures are not in direct contact, and each part can independently and stably realize the function. The M2 bolt of the terminal surface installation high accuracy of both wings, adjusting bolt twists the degree of depth, can finely tune the barycenter position of No. 4 structure for the barycenter of No. 4 structure and the barycenter coincidence of No. 2 structure further make whole quality block structure be central symmetry and distribute.

Fig. 5 is a schematic structural composition diagram of a single-axis gravity gradiometer, in which a mass block a and a mass block B are coaxially sleeved up and down on a central niobium tube, a certain number of wires for passing constant current are fixed in the central niobium tube, and in a liquid helium temperature zone, the mass block a, the mass block B and the central niobium tube maintain high-precision coaxiality due to the complete diamagnetism of a superconductor. The suspension coil and the induction coil are coaxial with the central niobium tube in a mechanical fixing mode, the surface of the coil is close to the surface of the mass block, the suspension coil, the induction coil and gravity jointly restrain the movement of the mass block along the axial direction of the niobium tube, meanwhile, the upper induction coil and the lower induction coil form a differential current loop, and the differential current corresponds to the difference of the acceleration of the upper mass block and the lower mass block, namely the gravity gradient. In practical situations, due to reasons such as machining errors and assembly accuracy, a small amount of common-mode acceleration information is carried in the obtained differential current, and the purpose of achieving common-mode rejection leveling is to make the common-mode acceleration information carried in the differential current zero. Relevant theories and experiments prove that the change of the attitude of the mass block can cause the inductance change of the suspension coil and the induction coil.

The differential current obtained in practice carries a small amount of common-mode acceleration information because the upper and lower mass blocks, the suspension coil and the induction coil are not perfectly matched, i.e. the structures are not completely the same. The structure is different and mainly exists in the winding error of a planar coil, the inclination of coaxial suspension caused by the processing error of a central niobium tube and the like, the deviation can be compensated by finely adjusting the posture of the mass block in a coupling way, but the introduced structure for adjusting the posture cannot influence the motion characteristic of the measuring direction (axial direction), as shown in figure 5, two wing coil groups are arranged on two sides of the two wing structure of the mass block, the two wing coils generate magnetic fields orthogonal to the measuring direction, two degrees of freedom of the posture of the mass block can be controlled, and the two wing coils do not need to be completely the same under the same processing dimension. Taking the mass block a as an example, the two-wing coils are distributed and installed as shown in fig. 6, there are eight two-wing coils in total, the installation positions correspond to eight vertexes of the cuboid, a high-precision controllable current source is arranged in each two-wing coil loop, and the mass block can rotate along the Y direction and the Z direction by controlling the current in each coil. The electrical connections of the entire system are shown in fig. 7.

Referring to fig. 7, the operation leveling process of this system is as follows:

1) opening thermal switches H1, H2 and H3, injecting currents with proper sizes into the suspension coil loop and the induction coil loop respectively, closing H1 and H2 firstly, and then closing H3;

2) setting an actuator of the experimental platform to vibrate at a frequency far less than the inherent common mode frequency of the system;

3) observing whether the SQUID output is in a target range, if so, turning to (6), otherwise, turning to (4);

4) the current with the same magnitude is led into an A1-A7 loop, an A3-A5 loop, an A2-A8 loop, an A4-A6 loop, a B1-B7 loop, a B3-B5 loop, a B2-B8 loop and a B4-B6 loop;

5) slowly increasing the current of the A1-A7 loop and the current of the A2-A8 loop with the same magnitude, slowly reducing the current of the A3-A5 loop and the current of the A4-A6 loop with the same magnitude, slowly reducing the current of the B1-B7 loop and the current of the B2-B8 loop with the same magnitude, slowly increasing the current of the B3-B5 loop and the current of the B4-B6 loop with the same magnitude, observing the SQUID output, and turning to (6) when the common mode output proportion reaches the minimum;

6) setting an actuator of the experimental platform to vibrate at a frequency far greater than the inherent common mode frequency of the system;

7) slowly increasing the current of the A1-A7 loop and the current of the A4-A6 loop with the same magnitude, slowly reducing the current of the A3-A5 loop and the current of the A2-A8 loop with the same magnitude, slowly reducing the current of the B1-B7 loop and the current of the B4-B6 loop with the same magnitude, slowly increasing the current of the B3-B5 loop and the current of the B2-B8 loop with the same magnitude, observing the SQUID output, and turning to (8) when the common mode output proportion reaches the minimum;

8) observing whether the common-mode signal proportion of the SQUID output signals is in a target range, if so, turning to (9), otherwise, turning to (2);

9) and finishing leveling.