CN215867156U

CN215867156U - Translational gravity measuring device

Info

Publication number: CN215867156U
Application number: CN202122106425.9U
Authority: CN
Inventors: 涂海波; 孙恒; 刘坤; 刘孙君; 柳林涛
Original assignee: Institute of Precision Measurement Science and Technology Innovation of CAS
Current assignee: Institute of Precision Measurement Science and Technology Innovation of CAS
Priority date: 2021-09-01
Filing date: 2021-09-01
Publication date: 2022-02-18
Anticipated expiration: 2031-09-01

Abstract

The utility model discloses a translational gravity measuring device which comprises a frame, a sampling mass cylinder, a variable-pitch capacitive displacement sensor and a reed set, wherein the sampling mass cylinder is connected with the variable-pitch capacitive displacement sensor, one end of each of two or more reed sets is in insulated connection with the side wall of the sampling mass cylinder, and the other end of each reed set is in insulated connection with the inner wall of the frame. The sampling mass cylinder is provided with an upper gravity compensation coil and a lower gravity compensation coil which are connected in series respectively outside the upper end and the lower end, and an upper gravity measurement coil and a lower gravity measurement coil which are connected in series respectively. The utility model eliminates the deflection motion mode of the sampling quality cylinder from the principle and realizes the translation motion of the sampling quality cylinder in the measuring process; the displacement measurement precision is improved; the heat dissipation area of the coil is increased, the assembly is easy, and the size is obviously reduced.

Description

Translational gravity measuring device

Technical Field

The utility model belongs to the technical field of gravity measurement, and particularly relates to a translational gravity measuring device.

Background

The gravity measurement of a moving base with a ship or an airplane as a carrier is one of important means for acquiring high-precision gravity data of the earth surface, and the result of the gravity measurement has important application in the fields of geodetic survey, resource exploration and the like (Lacost L.J.B., Reviews of geophysics,1967(5),477, Forsberg R.et al, 2015(6),265, Hu et al, Navigation position & Timing,2017(4), 10). The moving base gravimetric measurement is a good balance of measurement accuracy and efficiency-portable gravimeters have high accuracy but low measurement efficiency, while satellite gravimetric measurement has high efficiency but low accuracy in the short wavelength portion of gravity (Crossley d.et. al., Reports on progress in physics,2013(76), 046101; Jiang t.and Wang y.m., j.of Geodesy,2016(90), 1). Currently, various models of movable-base gravimeters are continuously developed at home and abroad, and the precision of the designed instruments reaches milli-gamma level or even higher (Zhang Z.B.et al, Marine Sciences,2015(39), 85; student M.et al, Geophysics,2008(73), 151; Cai S.K.et al, Science China: Earth Sciences,2013(56), 2198).

The movable base gravity measurement with higher precision is difficult to realize in engineering, because the disturbance acceleration of the carrier can be millions of times larger than the abnormal acceleration of the gravity to be measured, and the disturbance acceleration and the abnormal acceleration are overlapped and difficult to distinguish. With the development of global positioning systems, it has become possible to resolve the disturbance acceleration of the carrier to milligal magnitude independently by GNSS, and it is therefore expected that this disturbance acceleration is subtracted from the gravimetric measurement data, which is particularly important for airborne gravimetric measurements (Kennedy s.l.et., International Association of Geoesy Symposia,2002(125), 211; Bruton a.m.et., GPS solutions,2002(5), 1). In general, the moving-base gravimeters can be classified into two types according to the platform. A strapdown gravimeter and a gyro platform gravimeter; the gravity sensitive probe can be constructed in various forms, such as high precision quartz pendulum accelerometers, precision pendulums, precision spring structures, etc. used in Chekan, ZLS, GT and KSS (Zhang x.y.et al, Hydrographic Surveying and Charting,2012(25),71), respectively.

Among a plurality of sensitive probes for gravity measurement, a quartz pendulum accelerometer is applied to gravimeters of various types due to small size, and the probe is from the mature technology of a high-precision inertial navigation system and has a larger nonlinear effect when used for gravity measurement; the inclined-pulling type precise pendulum body probe with mechanical amplification capacity represented by ZLS has extremely high sensitivity, the technology is sourced from a static gravimeter of L & R company, however, the nonlinear effect in dynamic measurement is obvious and difficult to correct (Yuan Y.et al, Earth, planets and space,2020, 72); precision elastic gravimetric measurement structures, represented by KSS and GT, are a class of probes that have proven to be highly accurate in current commercial applications, and have the disadvantages of large volume and weight, high price, multiple wire drawing and spring constraints for the elastic structures, and complex assembly processes and processes.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a novel translational gravity measurement sensitive structure aiming at the defects in the prior art.

In order to achieve the purpose, the utility model adopts the following technical measures:

a translational gravity measuring device comprises a frame, a sampling mass cylinder, a variable-interval capacitance displacement sensor and a reed set,

the upper end of the sampling mass cylinder extends into the upper magnetic cylinder, the lower end of the sampling mass cylinder extends into the lower magnetic cylinder, the upper magnetic cylinder is connected with the inner wall of the top of the frame, and the lower magnetic cylinder is connected with the inner wall of the bottom of the frame; an upper magnetic conduction block is arranged in the upper end of the sampling mass cylinder, a lower magnetic conduction block is arranged in the lower end of the sampling mass cylinder, the upper magnetic conduction block is connected with the inside of the upper magnetic cylinder through an upper permanent magnet, and the lower magnetic conduction block is connected with the inside of the lower magnetic cylinder through a lower permanent magnet; the upper end outside and the lower end outside of the sampling quality cylinder are respectively provided with an upper gravity compensation coil and a lower gravity compensation coil which are connected in series, the upper end outside and the lower end outside of the sampling quality cylinder are also respectively provided with an upper gravity measurement coil and a lower gravity measurement coil which are connected in series,

the sampling mass cylinder is connected with the variable-pitch capacitance displacement sensor, one end of each of two or more than two reed sets is connected with the side wall of the sampling mass cylinder in an insulating way, the other end of each reed set is connected with the inner wall of the frame in an insulating way,

the upper gravity compensation coil and the upper gravity measurement coil are both positioned in a gap between the outer wall of the upper end of the sampling mass cylinder and the inner wall of the upper magnetic cylinder; and the lower gravity compensation coil and the lower gravity measurement coil are both positioned in a gap between the outer wall of the lower end of the sampling mass cylinder and the inner wall of the lower magnetic cylinder.

The variable-spacing type capacitance displacement sensor comprises a capacitance moving piece, a capacitance upper fixed piece and a capacitance lower fixed piece, wherein the capacitance moving piece is arranged at the periphery of the middle part of the sampling mass cylinder in an insulating mode, the capacitance moving piece is located between the capacitance upper fixed piece and the capacitance lower fixed piece, a capacitance conducting layer is arranged on the capacitance moving piece, the capacitance upper fixed piece and the capacitance lower fixed piece are respectively connected with a frame in an insulating mode, and the capacitance moving piece is respectively insulated with an upper gravity compensation coil, a lower gravity compensation coil, an upper gravity measurement coil and a lower gravity measurement coil.

As above the electric capacity rotor establish the annular piece of fixing at the middle part of sampling quality section of thick bamboo for insulating cover, stator all includes annular stator and stator connecting piece under stator and the electric capacity on the electric capacity, the annular stator passes through stator connecting piece and frame inner wall insulated connection, the sampling quality section of thick bamboo runs through the annular stator of stator and electric capacity on the electric capacity in proper order, the equal perpendicular to the central axis of sampling quality section of thick bamboo of stator under electric capacity rotor, the electric capacity.

The projections of the respective groups of reed along the central axis of the sampling mass cylinder as described above coincide. Each reed group comprises a plurality of independent reed strips which are parallel to each other, each reed strip of each reed group is positioned on the same plane, each reed strip of each reed group is insulated, and two ends of each reed strip of each reed group are connected with the inner wall of the frame and the sampling mass cylinder in an insulated mode.

The two ends of the upper gravity compensation coil and the lower gravity compensation coil which are connected in series, the two ends of the upper gravity measurement coil and the lower gravity measurement coil which are connected in series, and the capacitor moving plate are respectively connected with the corresponding reed strips and are connected with an external lead through the reed strips.

The upper and lower gravity measurement coils as described above are replaced by upper and lower damping coils, respectively.

The utility model provides a translational gravity measuring device, still include last damping coil and lower damping coil of establishing ties, it all is located the clearance between sampling mass section of thick bamboo upper end outer wall and the last magnetic cylinder inner wall to go up damping coil, lower damping coil all is located the clearance between sampling mass section of thick bamboo lower extreme outer wall and the lower magnetic cylinder inner wall, go up damping coil and lower damping coil vertical symmetry distribution, it is insulating with variable-pitch formula capacitance displacement sensor to go up damping coil and lower damping coil, the last damping coil of establishing ties and the reed strip that corresponds in the reed group are connected and are connected with the external conductor through the reed strip with lower damping coil both ends.

Compared with the prior art, the utility model has the following beneficial effects:

(1) different from arc motion of a pendulum piece of a quartz pendulum accelerometer in the measurement process, the measurement nonlinearity is caused; the utility model adopts a sampling mass constraint mode of the reed set, eliminates the deflection motion mode of the sampling mass cylinder and realizes the translational motion of the sampling mass cylinder in the measurement process. (2) Due to the translation motion, the capacitance displacement sensing area can be increased, and the displacement measurement precision is improved. (3) The coils are distributed in groups and are divided into an upper gravity compensation coil, a lower gravity compensation coil and an upper gravity measurement coil (the upper damping coil and the lower damping coil are integrated), or the coils are divided into the upper gravity compensation coil, the lower gravity compensation coil, the upper gravity measurement coil and the lower damping coil, so that the measurement precision is improved. The coils are distributed on the long cylindrical sampling mass cylinder, so that the heat dissipation area is increased, and the local temperature rise is reduced. The gravity balance springs of GT and ZLS gravimeters are removed, and the drifting and instrument lattice-falling errors caused by the creep and sudden jump of the main spring structure are eliminated. (4) Compared with probes with complex wire drawing structures such as a KSS type gravimeter and the like, the probe is easy to assemble, and the volume and the mass of the probe are obviously reduced. (5) The reed group is simultaneously used as a lead, so that the additional influence of the lead on the measurement is reduced.

Drawings

FIG. 1 is a perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic view of a reed assembly;

FIG. 3 is a schematic diagram of the movement of a sampling mass cylinder and the strip deformation of a reed under the constraint of a reed group;

FIG. 4 is a schematic view of the arrangement of the lower magnetic cylinder and the lower magnetic conductive block;

FIG. 5 is a block diagram of the distribution of coils on a sample mass and their wire connections; wherein the black line represents the gravity compensation loop and the gray line represents the gravity measurement loop;

FIG. 6 is a schematic front view of the present invention;

FIG. 7 is a schematic front sectional view of the present invention;

fig. 8 is a perspective view of a second perspective view according to the present invention.

In the figure: 1-a frame; 2-sampling a quality cylinder; 3-a variable-pitch capacitive displacement sensor; 4-a reed group; 5-upper gravity measurement coil; 6-lower gravity measurement coil; 7-upper gravity compensation coil; 8-lower gravity compensation coil; 9-upper magnetic cylinder; 10-lower magnetic cylinder; 11-upper magnetic conduction block; 12-lower magnetic conduction block; 13-upper permanent magnet; 14-lower permanent magnet; 301-capacitive moving plate; 302-capacitor top stator; 303-capacitive bottom plate.

Detailed Description

The present invention will be described in further detail with reference to examples for the purpose of facilitating understanding and practice of the utility model by those of ordinary skill in the art, and it is to be understood that the present invention has been described in the illustrative embodiments and is not to be construed as limited thereto.

A translational gravity measuring device comprises a frame 1, a sampling mass cylinder 2, a variable-pitch capacitive displacement sensor 3 and a reed set 4,

frame 1: and is fixedly connected with the frame of the gravity measuring platform. The frame 1 can be a hollow cuboid, a medium-sized cylinder and other structural types. The upper and lower permanent magnets, the upper and lower magnetic cylinders, and the upper and lower magnetic conductive blocks are all fixedly connected with the frame.

Sampling mass cylinder 2: the sampling quality cylinder 2 is cylindrical, the upper end of the sampling quality cylinder 2 extends into the upper magnetic cylinder 9, the lower end of the sampling quality cylinder 2 extends into the lower magnetic cylinder 10, the upper magnetic cylinder 9 is connected with the inner wall of the top of the frame 1, and the lower magnetic cylinder 10 is connected with the inner wall of the bottom of the frame 1; an upper magnetic conduction block 11 is arranged in the upper end of the sampling mass cylinder 2, a lower magnetic conduction block 12 is arranged in the lower end of the sampling mass cylinder 2, the upper magnetic conduction block 11 is connected with the inside of the upper magnetic cylinder 9 through an upper permanent magnet 13, and the lower magnetic conduction block 12 is connected with the inside of the lower magnetic cylinder 10 through a lower permanent magnet 14; an upper gravity compensation coil 7 and a lower gravity compensation coil 8 are respectively arranged outside the upper end and the lower end of the sampling mass cylinder 2, and an upper gravity measurement coil 5 and a lower gravity measurement coil 6 are respectively arranged outside the upper end and the lower end of the sampling mass cylinder 2. The upper gravity compensation coil 7 and the lower gravity compensation coil 8 are connected in series, and the upper gravity measurement coil 5 and the lower gravity measurement coil 6 are connected in series.

As another embodiment, the upper gravity measuring coil 5 integrates the function of an upper damping coil, and the lower gravity measuring coil 6 integrates the function of a lower damping coil.

As another embodiment, in addition to the upper gravity compensation coil 7, the lower gravity compensation coil 8, the upper gravity measurement coil 5, and the lower gravity measurement coil 6, the upper outer portion and the lower outer portion of the sampling mass cylinder 2 are respectively provided with an upper damping coil and a lower damping coil, which are connected in series.

The utility model adopts a coil and magnetic field layout which is symmetrical up and down. Namely, the upper magnetic cylinder 9 and the lower magnetic cylinder 10 are symmetrically distributed, the upper magnetic conduction block 11 and the lower magnetic conduction block 12 are symmetrically distributed up and down, the upper permanent magnet 13 and the lower permanent magnet 14 are symmetrically distributed up and down, the upper gravity compensation coil 7 and the lower gravity compensation coil 8 are symmetrically distributed up and down, the upper gravity measurement coil 5 and the lower gravity measurement coil 6 are symmetrically distributed up and down, and the upper damping coil and the lower damping coil are symmetrically distributed up and down.

The upper gravity compensation coil 7, the upper gravity measurement coil 5 and the upper damping coil are all positioned in a gap between the outer wall of the upper end of the sampling mass cylinder 2 and the inner wall of the upper magnetic cylinder 9; the lower gravity compensation coil 8, the lower gravity measurement coil 6 and the lower damping coil are all positioned in a gap between the outer wall of the lower end of the sampling mass cylinder 2 and the inner wall of the lower magnetic cylinder 10.

The upper permanent magnet 13 makes the gap between the upper magnetic cylinder and the lower magnetic conductive block made of magnetic conductive material full of radial uniform magnetic field, and the lower permanent magnet 14 makes the gap between the lower magnetic cylinder and the lower magnetic conductive block made of magnetic conductive material full of radial magnetic field. Due to the small gap, the magnetic field is approximately a uniform magnetic field. According to the formula F ═ BIL, where B is the magnetic field strength, L is the coil length, and I is the coil current, the magnetic force corresponding to each coil can be obtained.

The upper gravity compensation coil 7 and the lower gravity compensation coil 8 are driven by a constant current source, and the magnetic force of the upper gravity compensation coil and the lower gravity compensation coil is used for balancing the static gravity of the sampling mass cylinder 2, so that the sampling mass cylinder 2 is suspended between the upper magnetic cylinder 9 and the lower magnetic cylinder 10, and the capacitor moving plate 301 is suspended between the capacitor upper stator 302 and the capacitor lower stator 303; the upper gravity measurement coil 5 and the lower gravity measurement coil 6 obtain the displacement and the relative movement speed of the sampling mass cylinder 2 relative to the frame 1 according to the variable-pitch capacitive displacement sensor 3, and control operation is performed to obtain control current, and the control current is sent to the upper gravity measurement coil 5 and the lower gravity measurement coil 6, so that the output of the variable-pitch capacitive displacement sensor 3 is a set value (a typical value is zero), and the capacitive moving plate 301 connected with the sampling mass cylinder 2 is suspended at the central position of a gap formed by the capacitive upper stator plate 302 and the capacitive lower stator plate 303. The control current contains high frequency vibration and low frequency gravity change information for extracting the gravity measurement signal.

After the displacement and the relative movement speed of the sampling mass cylinder 2 relative to the frame 1 are obtained by the variable-pitch capacitive displacement sensor 3, the damping circuit applies proportional damping current to the upper damping coil and the lower damping coil which are connected in series, and the corresponding electromagnetic force is opposite to the speed direction and plays a damping role. The damping current can also be sent to the upper gravity compensation coil and the lower gravity compensation coil which are connected in series through the addition circuit, and the upper gravity compensation coil and the lower gravity compensation coil which are connected in series play a damping role at the same time.

Variable-pitch capacitive displacement sensor 3: including stator 302 under condenser moving plate 301, the condenser and the condenser 303, the insulating condenser moving plate 301 that is provided with in middle part periphery of sampling quality section of thick bamboo 2, condenser moving plate 301 is located condenser and goes up between stator 302 and the condenser 303, is provided with the condenser conducting layer on the condenser moving plate 301, and stator 303 is connected with frame 1 insulation respectively under stator 302 and the condenser on the condenser. The capacitance moving plate 301 is in insulation connection with the sampling mass cylinder 2, the capacitance moving plate 301 is respectively insulated from the upper gravity compensation coil 7, the lower gravity compensation coil 8, the upper gravity measurement coil 5 and the lower gravity measurement coil 6, or the capacitance moving plate 301 is respectively insulated from the upper gravity compensation coil 7, the lower gravity compensation coil 8, the upper damping coil and the lower damping coil, or the capacitance moving plate 301 is respectively insulated from the upper gravity compensation coil 7, the lower gravity compensation coil 8, the upper gravity measurement coil 5, the lower gravity measurement coil 6, the upper damping coil and the lower damping coil. Namely, the variable-pitch capacitive displacement sensor 3 is insulated from each of the coil, the frame 1, and the sampling mass cylinder 2.

As a preferred scheme, electric capacity movable plate 301 establishes the annular piece of fixing in the middle part of sampling quality section of thick bamboo 2 for insulating cover, and electric capacity upper stator piece 302 and electric capacity lower stator piece 303 all include annular stator piece and stator connecting piece, and the annular stator piece passes through stator connecting piece and frame 1 inner wall insulated connection, and sampling quality section of thick bamboo 2 runs through electric capacity upper stator piece 302 and electric capacity lower stator piece 303's annular stator piece in proper order.

The capacitance moving plate 301, the capacitance upper stator plate 302 and the capacitance lower stator plate 303 are all perpendicular to the central axis of the sampling mass cylinder 2. The movement of the movable capacitor plate 301 causes a change in the distance between the movable capacitor plate 301 and the upper and lower fixed

capacitor plates

302 and 303, thereby causing a change in the capacitance between the upper and lower fixed

capacitor plates

302 and 303, and the change in the capacitance between the upper and lower fixed

capacitor plates

302 and 303 is detected by a differential circuit, thereby measuring the change in the displacement of the sampling mass cylinder 2 along the central axis of the sampling mass cylinder 2. According to the prior art, the displacement detection resolution is better than 0.1nm, and the repeatability is better than 1 nm.

The variable-pitch capacitive displacement sensor 3 adopts a sandwich structure, a capacitor moving plate 301 is positioned between a capacitor upper fixed plate 302 and a capacitor lower fixed plate 303, when the capacitor moving plate 301 deviates from a balance position, the capacitance of the capacitor upper fixed plate 302 and the capacitance of the capacitor lower fixed plate 303 which are parallel up and down are increased and decreased one by one, and the change of the capacitance between the capacitor upper fixed plate 302 and the capacitor lower fixed plate 303 is detected through a differential circuit. Has good linearity at small displacements in the direction of the central axis (z direction) of the sampling mass cylinder 2.

V＝k_c·ΔC≈k_c·2ε₀SΔz/d²≡k_z·Δz，

Wherein，k_zFor the calibration coefficient of the variable-pitch capacitive displacement sensor 3, S is the area directly facing the capacitor plate, i.e. the overlapping area of the capacitor rotor 301 and the capacitor upper stator or the capacitor lower stator 303 in the central axis direction of the sampling mass cylinder 2, the capacitor upper stator or the capacitor lower stator 303 coincides in the central axis direction of the sampling mass cylinder, Δ z is the displacement distance of the capacitor rotor 301 along the central axis direction of the sampling mass cylinder 2, and d is the capacitor plate pitch, i.e. the distance of the gap between the surface of the capacitor upper stator or the capacitor lower stator and the rotor surface. During normal operation, the upper and lower clearances will be equal, in this application of 1 mm magnitude. According to the prior art, the detection resolution of the variable-pitch capacitive displacement sensor 3 is better than 0.1 nm.

And a reed group 4: the number of the reed sets 4 is multiple, each reed set 4 is respectively connected with the sampling mass cylinder 2 and the inner wall of the frame 1 in an insulation manner, the central axis of each reed set 4 is perpendicular to the central axis of the sampling mass cylinder 2, the reed sets 4 are arranged at intervals (for example, in centimeter magnitude), and the projections of the reed sets 4 along the central axis of the sampling mass cylinder 2 are overlapped. Each reed group comprises a plurality of independent reed strips which are parallel to each other, each reed strip of each reed group is positioned on the same plane, each reed strip of each reed group is insulated, two ends of each reed strip of each reed group are insulated and connected with the inner wall of the frame and the sampling mass cylinder 2, the reed strips can be insulated and connected in an insulating flat plate clamping or insulating bonding mode, two ends of an upper gravity compensation coil 7 and a lower gravity compensation coil 8 which are connected in series, two ends of an upper gravity measurement coil 5 and a lower gravity measurement coil 6 which are connected in series, two ends of an upper damping coil and a lower damping coil which are connected in series, a capacitor dynamic sheet and a temperature sensor arranged in the frame are respectively connected with the corresponding reed strips, and the connection with an external lead is realized through the reed strips.

In the present embodiment, the number of the leaf groups 4 is two.

Under the constraint of the reed group 4, only one translational degree of freedom of the sampling mass cylinder 2 in the vertical direction is low in mechanical rigidity, and the sampling mass cylinder is used for accurately sensing gravity change, and the rigidity of the sampling mass cylinder is the mechanical rigidity of the reed group 4 serving as a cantilever beam. When the sampling quality cylinder 2 moves up and down in a translational mode, the connection position of the reed group 4 and the sampling quality cylinder 2 has slight translational motion along the horizontal direction, and the amplitude of the translational motion is as follows:

wherein z is the up-and-down motion amplitude of the sampling mass cylinder 2, x is the translational motion amplitude of the joint of the reed set 4 and the sampling mass cylinder 2 along the horizontal direction, and L is the length of the reed set 4. As can be seen from the above equation, the horizontal motion of the sampling mass cylinder 2 is a second order small quantity, proportional to the square of the amplitude of the motion of the sampling mass cylinder 2 along the central axis, and inversely proportional to the reed length. On the one hand, the motion amplitude is very small, for example, usually z is in the order of 10 μm, L is in the order of 2cm, and x is in the order of 10nm and smaller than z by three orders; on the other hand, the capacitance displacement sensor in the vertical direction measures the change of the distance between the moving plate and the fixed plate, and is theoretically decoupled from the horizontal motion of the sampling mass, so that the motion mode can be ignored.

The utility model adopts two or more than two reed groups to restrain the irrelevant movement mode of the sampling quality cylinder 2 (namely movement except along the central axis direction of the sampling quality cylinder 2), and realizes translational gravity measurement of the sampling quality cylinder 2. The nonlinearity of the existing pendulum structure is overcome, and the drifting and lattice falling caused by the spring in the existing vertical spring or inclined pull spring type gravimeter are avoided. The utility model has simplified assembly, symmetrical and compact whole structure, greatly reduced size and mass of the gravity probe, and improved measurement accuracy.

The utility model adopts the motion constraint mode of the reed set to provide a translational sensitive degree of freedom, namely the degree of freedom along the axis of the sampling mass cylinder, namely the z degree of freedom, for the sampling mass cylinder 2 in gravity measurement. In the plane of the gravity measurement direction, the above constraint can be realized as long as two or more reed sets are arranged, and the rigidity of other degrees of freedom of the sampling mass cylinder 2 is infinite compared with the gravity measurement degree of freedom, which is equivalent to being fixedly connected with a frame.

The formula for the stiffness k of the spring set 4 in the direction of gravity measurement (z degrees of freedom) is:

k＝nEwt³/12L，

wherein n is the number of the reed strips, E is the Young modulus of the material, and w, t and L are the width, thickness and length of the reed strips respectively.

The foregoing detailed description is given for the sole purpose of illustration, and is not to be construed as limiting the scope of the utility model, as those skilled in the art will recognize that various modifications, additions and substitutions can be made to the detailed description without departing from the spirit of the utility model or exceeding the scope of the claims set forth below.

Claims

1. A translational gravity measuring device comprises a frame (1), and is characterized by also comprising a sampling mass cylinder (2), a variable-pitch capacitive displacement sensor (3) and a reed group (4),

the upper end of the sampling mass cylinder (2) extends into the upper magnetic cylinder (9), the lower end of the sampling mass cylinder (2) extends into the lower magnetic cylinder (10), the upper magnetic cylinder (9) is connected with the inner wall of the top of the frame (1), and the lower magnetic cylinder (10) is connected with the inner wall of the bottom of the frame (1); an upper magnetic conduction block (11) is arranged in the upper end of the sampling mass cylinder (2), a lower magnetic conduction block (12) is arranged in the lower end of the sampling mass cylinder (2), the upper magnetic conduction block (11) is connected with the inside of the upper magnetic cylinder (9) through an upper permanent magnet (13), and the lower magnetic conduction block (12) is connected with the inside of the lower magnetic cylinder (10) through a lower permanent magnet (14); an upper gravity compensation coil (7) and a lower gravity compensation coil (8) which are connected in series are respectively arranged outside the upper end and the lower end of the sampling mass cylinder (2), an upper gravity measurement coil (5) and a lower gravity measurement coil (6) which are connected in series are respectively arranged outside the upper end and the lower end of the sampling mass cylinder (2),

the sampling mass cylinder (2) is connected with the variable-pitch capacitive displacement sensor (3), one end of two or more than two reed sets (4) is connected with the side wall of the sampling mass cylinder (2) in an insulating way, the other end is connected with the inner wall of the frame (1) in an insulating way,

the upper gravity compensation coil (7) and the upper gravity measurement coil (5) are both positioned in a gap between the outer wall of the upper end of the sampling mass cylinder (2) and the inner wall of the upper magnetic cylinder (9); the lower gravity compensation coil (8) and the lower gravity measurement coil (6) are both positioned in a gap between the outer wall of the lower end of the sampling mass cylinder (2) and the inner wall of the lower magnetic cylinder (10).

2. The translational gravity measuring device according to claim 1, wherein the variable-pitch capacitive displacement sensor (3) comprises a capacitive moving plate (301), a capacitive upper fixed plate (302) and a capacitive lower fixed plate (303), the capacitive moving plate (301) is arranged on the periphery of the middle of the sampling mass cylinder (2) in an insulating mode, the capacitive moving plate (301) is located between the capacitive upper fixed plate (302) and the capacitive lower fixed plate (303), a capacitive conducting layer is arranged on the capacitive moving plate (301), the capacitive upper fixed plate (302) and the capacitive lower fixed plate (303) are respectively connected with the frame (1) in an insulating mode, and the capacitive moving plate (301) is respectively insulated from the upper gravity compensation coil (7), the lower gravity compensation coil (8), the upper gravity measurement coil (5) and the lower gravity measurement coil (6).

3. The translational gravity measuring device according to claim 2, wherein the capacitor moving plate (301) is an annular plate fixed in the middle of the sampling mass cylinder (2) for insulation, the capacitor upper stator plate (302) and the capacitor lower stator plate (303) both comprise an annular stator plate and a stator plate connecting member, the annular stator plate is connected with the inner wall of the frame (1) in an insulation manner through the stator plate connecting member, the sampling mass cylinder (2) sequentially penetrates through the annular stator plates of the capacitor upper stator plate (302) and the capacitor lower stator plate (303), and the capacitor moving plate (301), the capacitor upper stator plate (302) and the capacitor lower stator plate (303) are all perpendicular to the central axis of the sampling mass cylinder (2).

4. The translational gravity measuring device according to claim 1, wherein the projections of the reed groups (4) along the central axis of the sampling mass cylinder (2) are coincident, each reed group comprises a plurality of independent reed strips which are parallel to each other, the reed strips of each reed group are positioned on the same plane, the reed strips of each reed group are insulated, and two ends of the reed strips of each reed group are connected with the inner wall of the frame and the sampling mass cylinder (2) in an insulated manner.

5. A translational gravity measuring device according to claim 4, wherein the two ends of the upper gravity compensation coil (7) and the lower gravity compensation coil (8) connected in series, the two ends of the upper gravity measurement coil (5) and the lower gravity measurement coil (6) connected in series, and the capacitive rotor are connected to the corresponding reed bars respectively, and are connected to external leads through the reed bars.

6. The translational gravity measuring device according to claim 1, further comprising an upper damping coil and a lower damping coil connected in series, wherein the upper damping coil is located in a gap between an outer wall of an upper end of the sampling mass cylinder (2) and an inner wall of the upper magnetic cylinder (9), the lower damping coil is located in a gap between an outer wall of a lower end of the sampling mass cylinder (2) and an inner wall of the lower magnetic cylinder (10), the upper damping coil and the lower damping coil are vertically and symmetrically distributed, the upper damping coil and the lower damping coil are insulated from the variable-pitch capacitive displacement sensor (3), and two ends of the upper damping coil and the lower damping coil connected in series are connected with corresponding reed bars in the reed group (4) and are connected with an external lead through the reed bars.