CN204731265U - A kind of MEMS triaxial accelerometer - Google Patents

Abstract

The utility model discloses MEMS triaxial accelerometer, comprise substrate and the twisting mass being suspended in surface; Symmetrical structure centered by twisting mass, comprises parenchyma gauge block and first, second inferior quality block, and is parallel to four elasticity tie-beams of y-axis; First time, the left side lateral edges of mass was connected with parenchyma gauge block by the first elasticity tie-beam, and the right side/left side edge of second time mass is connected with parenchyma gauge block by the second elasticity tie-beam; First time, the center of mass was connected on the first anchor point of substrate by the 3rd elasticity tie-beam, and the center of second time mass is connected on the second anchor point of substrate by the 4th elasticity tie-beam; First, second inferior quality block is provided with first, second, third movable electrode, substrate is provided with first, second, third fixed electorde forming x-axis, y-axis, z-axis Detection capacitance with first, second, third movable electrode.The utility model can eliminate external interference, and process for making is simple and easy to realize.

Description

MEMS triaxial accelerometer

Technical Field

The utility model relates to a sensor technical field, more specifically relates to a MEMS triaxial accelerometer.

Background

Micro-electromechanical accelerometers are inertial devices based on MEMS technology for measuring linear motion acceleration of object motion. The novel high-voltage switch has the characteristics of small volume, high reliability, low cost, suitability for mass production and the like, so that the novel high-voltage switch has a wide market prospect, and the application fields of the novel high-voltage switch comprise consumer electronics, aerospace, automobiles, medical equipment, weapons and the like.

At present, the size of a chip of the MEMS accelerometer is smaller and smaller, so the MEMS triaxial accelerometer is prone to a triaxial integrated single structure design, but due to the limitation of a z-axis detection structure, most of integrated MEMS triaxial accelerometers adopt a design eccentric in a certain direction to complete the simultaneous detection of three axial accelerations by a single structure.

The eccentric integrated MEMS triaxial accelerometer is usually designed asymmetrically, which has special requirements on the manufacturing process on one hand and cannot completely eliminate the influence of external interference factors on the other hand.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a new technical scheme of MEMS triaxial accelerometer of full symmetric structure.

According to the utility model discloses an aspect provides a MEMS triaxial accelerometer, include: a substrate; a torsional mass suspended above the substrate; the plane of the twisting mass block is an xy plane, wherein the positive direction of an x axis points to the right side of the xy plane, and the positive direction of a y axis points to the upper side of the xy plane; the twisting mass block is of a central symmetry structure and comprises a main mass block, a first secondary mass block positioned on the left side of the main mass block, a second secondary mass block positioned on the right side of the main mass block, and a first elastic connecting beam, a second elastic connecting beam, a third elastic connecting beam and a fourth elastic connecting beam which are parallel to the y axis; the left/right edges of the first secondary mass blocks are connected with the main mass blocks through first elastic connecting beams, and the right/left edges of the second secondary mass blocks are connected with the main mass blocks through second elastic connecting beams; the center of the first secondary mass block is connected to a first anchor point of the substrate through a third elastic connecting beam, and the center of the second secondary mass block is connected to a second anchor point of the substrate through a fourth elastic connecting beam; the first secondary mass block and the second secondary mass block are respectively provided with a first movable electrode, a second movable electrode and a third movable electrode; the substrate is provided with a first fixed electrode, a second fixed electrode and a third fixed electrode which are used for respectively forming an x-axis detection capacitor, a y-axis detection capacitor and a z-axis detection capacitor with the first movable electrode, the second movable electrode and the third movable electrode.

Preferably, the z-axis detection capacitor is a plate capacitor, the third movable electrode is an upper electrode, and the third fixed electrode is a lower electrode; the number of the third movable electrodes is four, the three movable electrodes are respectively arranged at the left edge and the right edge of the first secondary mass block and the second secondary mass block, the third fixed electrodes and the third movable electrodes are in one-to-one correspondence, and a first, a second, a third and a fourth z-axis detection capacitors are sequentially formed from left to right; the first and fourth z-axis detection capacitors are connected in parallel to form a first group of z-axis detection capacitors, the second and third z-axis detection capacitors are connected in parallel to form a second group of z-axis detection capacitors, and the first group of z-axis detection capacitors and the second group of z-axis detection capacitors form a pair of z-axis differential detection capacitors.

Preferably, the left side and the right side of the first secondary mass block and the second secondary mass block are respectively provided with a third through hole; the first fixed electrode is positioned inside the third through hole, and the first movable electrode corresponding to the first fixed electrode is arranged on the side edge of the third through hole.

Preferably, two first fixed electrodes which are parallel to each other left and right are arranged in each third through hole; the first movable electrode and the first fixed electrode are in one-to-one correspondence, and a first, a second, a third, a fourth, a fifth, a sixth, a seventh and an eighth x-axis detection capacitor are sequentially formed from left to right; the first, third, fifth and seventh x-axis detection capacitors are connected in parallel to form a first group of x-axis detection capacitors, the second, fourth, sixth and eighth x-axis detection capacitors are connected in parallel to form a second group of x-axis detection capacitors, and the first group of x-axis detection capacitors and the second group of x-axis detection capacitors form a pair of differential capacitors.

Preferably, the upper side and the lower side of the first secondary mass block and the second secondary mass block are respectively provided with a fourth through hole; the second fixed electrode is positioned inside the fourth through hole, and the second movable electrode corresponding to the second fixed electrode is arranged on the side edge of the fourth through hole.

Preferably, two second fixed electrodes which are parallel to each other at the left and right sides are arranged in each fourth through hole; the second movable electrodes correspond to the second fixed electrodes one by one, so that a first y-axis detection capacitor and a second y-axis detection capacitor are sequentially formed on the upper side of the first mass block from left to right, a third y-axis detection capacitor and a fourth y-axis detection capacitor are sequentially formed on the lower side of the first mass block from left to right, a fifth y-axis detection capacitor and a sixth y-axis detection capacitor are sequentially formed on the upper side of the second mass block from left to right, and a seventh y-axis detection capacitor and an eighth y-axis detection capacitor are sequentially formed on the lower side of the second mass block from left to right; the first, fourth, sixth and seventh y-axis detection capacitors are connected in parallel to form a first group of y-axis detection capacitors, the second, third, fifth and eighth y-axis detection capacitors are connected in parallel to form a second group of y-axis detection capacitors, and the first group of y-axis detection capacitors and the second group of y-axis detection capacitors form a pair of y-axis differential detection capacitors.

Preferably, a first through hole is formed in the center of the first secondary mass block, and a second through hole is formed in the center of the second secondary mass block; the third elastic connecting beam is arranged in the first through hole, two ends of the third elastic connecting beam are connected to the side wall of the first through hole, and the center of the third elastic connecting beam is connected to a first anchor point of the substrate; the fourth elastic connecting beam is arranged inside the second through hole, two ends of the fourth elastic connecting beam are connected to the side wall of the second through hole, and the center of the fourth elastic connecting beam is connected to the second anchor point of the substrate.

Preferably, two ends of the first elastic connecting beam are respectively connected with the main mass block, and the middle of the first elastic connecting beam is connected with the first secondary mass block; or the two ends of the first elastic connecting beam are respectively connected with the first secondary mass block and the middle of the first elastic connecting beam is connected with the main mass block, and the two ends of the second elastic connecting beam are respectively connected with the second secondary mass block and the middle of the second elastic connecting beam is connected with the main mass block.

Preferably, fifth through holes are formed in the left side and the right side of the main mass block respectively, the first secondary mass block is located inside the fifth through hole in the left side, and the second secondary mass block is located inside the fifth through hole in the right side.

Preferably, the x-axis detection capacitor and the y-axis detection capacitor are comb-teeth-shaped capacitors.

The utility model provides a MEMS triaxial accelerometer of holohedral symmetry structure can eliminate external interference factor's influence to manufacturing process is simple easily to be realized.

Other features of the present invention and advantages thereof will become apparent from the following detailed description of exemplary embodiments of the invention, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a schematic structural diagram of a first embodiment of the MEMS triaxial accelerometer of the present invention.

Fig. 2 is a schematic diagram of the x-axis acceleration detection of the first embodiment.

Fig. 3 is a schematic diagram of the principle of the y-axis acceleration detection of the first embodiment.

Fig. 4 and 5 are schematic diagrams illustrating the detection of z-axis acceleration in the first embodiment.

Fig. 6 is a schematic structural diagram of a second embodiment of the MEMS triaxial accelerometer of the present invention.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: unless specifically stated otherwise, the relative arrangement of the components and steps, the numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present invention.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses.

Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail, but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

Referring to fig. 1-5, a first embodiment of a MEMS triaxial accelerometer of the present invention is shown, wherein the MEMS triaxial accelerometer is a fully symmetric structure comprising a substrate 400 (not shown in fig. 1-3) and a torsional mass suspended above the substrate 400.

And constructing a three-dimensional rectangular coordinate system as shown in the figure, wherein the plane of the twisting mass block is an xy plane, and the positive direction of the z axis is directed to the twisting mass block from the substrate. Wherein the positive direction of the x-axis points to the right of the xy-plane and the positive direction of the y-axis points to the upper side of the xy-plane.

The torsional mass block is a centrosymmetric structure and comprises a main mass block 300, a first secondary mass block 100, a second secondary mass block 200, and a first elastic connecting beam, a second elastic connecting beam, a third elastic connecting beam and a fourth elastic connecting beam which are parallel to the y axis. The left and right sides of the main mass block 300 are respectively provided with a fifth through hole 405, the first secondary mass block 100 is located inside the fifth through hole 405 on the left side, and the second secondary mass block 200 is located inside the fifth through hole 405 on the right side.

In the first embodiment, the right side edge of the first secondary mass 100 is connected to the main mass 300 through the first elastic connection beam 301, and the left side edge of the second secondary mass 200 is connected to the main mass 300 through the second elastic connection beam 302. In other embodiments, it may also be: the left side edge of the first secondary mass 100 is connected to the main mass 300 through the first elastic connection beam 301, and the right side edge of the second secondary mass 200 is connected to the main mass 300 through the second elastic connection beam 302.

In the first embodiment, both ends of the first flexible connection beam 301 are respectively connected to the primary mass block 300 and the middle thereof is connected to the primary mass block 100, and both ends of the second flexible connection beam 302 are respectively connected to the primary mass block 300 and the middle thereof is connected to the secondary mass block 200. In other embodiments, it may also be: the first elastic connection beams 301 are connected at both ends to the first secondary mass block 100 and at the middle to the main mass block 300, respectively, and the second elastic connection beams 302 are connected at both ends to the second secondary mass block 200 and at the middle to the main mass block 300, respectively.

The first secondary mass 100 has a first through hole 401 at the center thereof, and the second secondary mass 200 has a second through hole 402 at the center thereof. The third elastic connection beam 303 is disposed inside the first through hole 401, two ends of the third elastic connection beam are connected to the sidewall of the first through hole 401, and the center of the third elastic connection beam is connected to the first anchor point 501 of the substrate. The fourth flexible connecting beam 304 is disposed inside the second through hole 402, and two ends of the fourth flexible connecting beam are connected to the sidewalls of the second through hole 402 and the center of the fourth flexible connecting beam is connected to the second anchor point 502 of the substrate. With the above arrangement, the proof mass is suspended above the substrate 400 by virtue of the support of the first and second anchors 501, 502.

The first secondary mass block 100 and the second secondary mass block 200 are respectively provided with a first movable electrode, a second movable electrode and a third movable electrode; the substrate 400 is provided with a first fixed electrode, a second fixed electrode, and a third fixed electrode for forming an x-axis detection capacitor, a y-axis detection capacitor, and a z-axis detection capacitor with the first movable electrode, the second movable electrode, and the third movable electrode, respectively.

The following describes the working principle of the MEMS triaxial accelerometer of the present invention, and for the x-axis mode, it is shown with reference to fig. 2: when acceleration in the x-axis direction is input, the main mass 300 is displaced to the left or the right. Since the first secondary mass 100 is fixed to the substrate only at the center thereof by the third elastic connection beams 303 in the y-axis direction, the first secondary mass 100 is also displaced leftward or rightward. Similarly, the second secondary mass 200 is also displaced to the left or right. Detecting this degree of displacement of the first and second secondary masses 100, 200 enables an acceleration of the x-axis to be obtained.

For this purpose, third through holes 403 are respectively formed on the left and right sides of the first secondary mass 100 and the second secondary mass 200, and two first fixed electrodes are arranged inside each third through hole 403 in parallel on the left and right sides. The whole MEMS accelerometer thus includes 8 first fixed electrodes, which are first fixed electrodes 11, 12, 13, 14, 15, 16, 17, 18 in sequence from left to right, and first movable electrodes (not shown in the figure) corresponding to the first fixed electrodes are disposed at the sides of the third through hole 403, so that first, second, third, fourth, fifth, sixth, seventh, and eighth x-axis detection capacitors are formed in sequence from left to right.

Although not shown in the drawings, it should be understood by those skilled in the art that the first movable electrode is disposed such that when the first secondary mass 100 or the second secondary mass 200 is displaced in the x-axis direction, the area or distance of the x-axis detection capacitor formed by the first movable electrode and the corresponding first fixed electrode is correspondingly changed, so as to change the capacitance of the x-axis detection capacitor, thereby achieving the detection of the acceleration in the x-axis direction.

A first movable electrode corresponding to the first fixed electrode 11 may be disposed on the left side of the first fixed electrode 11 and opposed to the first fixed electrode 11, and a first movable electrode opposed to the first fixed electrode 12 may be disposed on the right side of the first fixed electrode 12 and opposed to the first fixed electrode 12. The remaining first movable electrodes are similarly arranged. The first, third, fifth and seventh x-axis detection capacitors with capacitance increasing or decreasing simultaneously are connected in parallel to form a first group of x-axis detection capacitors, the second, fourth, sixth and eighth x-axis detection capacitors which change oppositely are connected in parallel to form a second group of x-axis detection capacitors, and the first group of x-axis detection capacitors and the second group of x-axis detection capacitors form a pair of differential capacitors.

The x-axis detection capacitor can be a flat plate-shaped or comb-shaped capacitor, and is preferably a comb-shaped capacitor.

For the y-axis mode, referring to FIG. 3: when acceleration in the y-axis direction is input, the main mass block 300 moves upwards or downwards to further drive the first mass block 100 and the second mass block 200, and the secondary mass blocks cannot translate in the y-axis direction because the centers of the secondary mass blocks are fixed on anchor points of the substrate through elastic connecting beams in the y-axis direction, and can only rotate around the respective anchor points by taking the respective anchor points as axes, wherein the rotating directions of the two secondary mass blocks are opposite. Specifically, when the acceleration direction is the y-axis forward direction, the primary mass block 300 moves upward, the primary mass block 100 twists in the counterclockwise direction, and the secondary mass block 200 twists in the clockwise direction; when the acceleration direction is negative y-axis, the primary mass 300 moves downward, the primary mass 100 twists clockwise, and the secondary mass 200 twists counterclockwise. Detecting the degree of torsion of the first secondary mass 100 and the second secondary mass 200 enables the acceleration of the y-axis to be obtained.

Therefore, fourth through holes 404 are respectively formed in the upper and lower sides of the first secondary proof mass 100 and the second secondary proof mass 200, and two second fixed electrodes which are parallel to each other in the left and right directions are respectively arranged in each fourth through hole 404. Thus, the whole MEMS accelerometer includes 8 second fixed electrodes, the second fixed electrodes 21 and 22 are sequentially disposed inside the fourth through hole 404 on the upper side of the first secondary mass block 100 from left to right, the second fixed electrodes 23 and 24 are sequentially disposed inside the fourth through hole 404 on the lower side of the first secondary mass block 100 from left to right, the second fixed electrodes 25 and 26 are sequentially disposed inside the fourth through hole 404 on the upper side of the second secondary mass block 200 from left to right, the second fixed electrodes 27 and 28 are sequentially disposed inside the fourth through hole 404 on the lower side of the second secondary mass block 200 from left to right, and the second movable electrodes (not shown in the figure) corresponding to the second fixed electrodes are disposed on the sides of the fourth through hole 404. Thus, a first y-axis detection capacitor and a second y-axis detection capacitor are sequentially formed on the upper side of the first mass block 100 from left to right, a third y-axis detection capacitor and a fourth y-axis detection capacitor are sequentially formed on the lower side of the first mass block from left to right, a fifth y-axis detection capacitor and a sixth y-axis detection capacitor are sequentially formed on the upper side of the second mass block 200 from left to right, and a seventh y-axis detection capacitor and an eighth y-axis detection capacitor are sequentially formed on the lower side of the second mass block 200 from left to right.

Although not shown in the drawings, it should be understood by those skilled in the art that the second movable electrode is disposed such that when the first secondary mass 100 or the second secondary mass 200 is twisted around the respective anchor point, the area or distance of the y-axis sensing capacitor formed by the second movable electrode and the corresponding second fixed electrode is correspondingly changed, so as to change the capacitance of the y-axis sensing capacitor, thereby achieving the detection of the acceleration in the y-axis direction.

A second movable electrode corresponding to the second fixed electrode 21 may be disposed on the left side of the second fixed electrode 21 and opposed to the second fixed electrode 21, and a second movable electrode opposed to the second fixed electrode 22 may be disposed on the right side of the second fixed electrode 22 and opposed to the second fixed electrode 12. The remaining second movable electrodes are similarly arranged. The first, fourth, sixth and seventh y-axis detection capacitors with capacitance simultaneously increased or decreased are connected in parallel to form a first group of y-axis detection capacitors, the second, third, fifth and eighth y-axis detection capacitors which are changed oppositely are connected in parallel to form a second group of y-axis detection capacitors, and the first group of y-axis detection capacitors and the second group of y-axis detection capacitors form a pair of y-axis differential detection capacitors.

The y-axis detection capacitor can be a flat plate-shaped or comb-shaped capacitor, and is preferably a comb-shaped capacitor.

For the z-axis mode, as shown with reference to fig. 4 and 5: when acceleration in the z-axis direction is input, the primary mass block 300 moves upwards or downwards to drive the secondary mass block to move, and the secondary mass block is fixed on an anchor point through a connecting beam in the center of the secondary mass block, so that the translation of the secondary mass block in the z-axis direction is limited, and only the elastic connecting beam can be used as a rotating shaft to rotate. Specifically, referring to fig. 4, when the direction of the acceleration is the negative z-axis direction, the main mass block 300 moves downward, the left half of the first mass block 100 moves upward, the right half moves downward, the left half of the second mass block 200 moves downward, and the right half moves upward. Referring to fig. 5, when the direction of the acceleration is the z-axis positive direction, the main mass block 300 moves upward, the left half of the first sub mass block 100 moves downward, the right half moves upward, and the left half of the second sub mass block 200 moves upward, and the right half moves downward.

For this purpose, as shown in fig. 4 and 5, the z-axis detection capacitor may be provided as a plate capacitor, the third movable electrode may be an upper electrode, and the third fixed electrode may be a lower electrode. The four third movable electrodes are respectively disposed at the left and right edges of the first secondary mass 100 and the second secondary mass 200, and are the third movable electrodes 31, 32, 33, and 34 from left to right. The third fixed electrodes and the third movable electrodes are disposed on the substrate 400 in a one-to-one correspondence, and the third fixed electrodes 31A, 32A, 33A, and 34A are sequentially formed from left to right, so that the first, second, third, and fourth z-axis detection capacitors are sequentially formed from left to right.

As can be seen from the foregoing, when z-direction acceleration is input, the distance between the two electrodes of the first and fourth z-axis detection capacitors increases or decreases simultaneously, and the change in the distance between the two electrodes of the second and third z-axis detection capacitors is opposite to that, so that the first and fourth z-axis detection capacitors can be connected in parallel to form a first set of z-axis detection capacitors, the second and third z-axis detection capacitors can be connected in parallel to form a second set of z-axis detection capacitors, and the first set of z-axis detection capacitors and the second set of z-axis detection capacitors form a pair of z-axis differential detection capacitors.

The first and second fixed electrodes in the first embodiment are fixed to the substrate 400 by anchor points 503, one of which anchor points 503 is schematically indicated in fig. 1.

The utility model discloses a MEMS triaxial accelerometer's structure is complete symmetry, can realize detecting the acceleration signal of the three direction of xyz simultaneously. The centers of the two secondary mass blocks are respectively provided with an anchor point, the secondary mass blocks are connected to the anchor points through the elastic connecting beams parallel to the y axis, and the edges of the secondary mass blocks are connected with the main mass block through the elastic connecting beams parallel to the y axis, so that a linkage structure is realized. The comb electrodes of the xy axis are distributed in the secondary mass block in a differential pair mode, and a certain gap is reserved between the comb electrodes and the secondary mass block, so that a differential detection capacitor of the xy axis is formed, and the detection of acceleration signals in the xy axis direction is realized. The lower electrode of the z-axis flat capacitor is distributed on the substrate below the secondary mass block, and a certain gap is reserved between the lower electrode and the lower surface of the secondary mass block, so that a z-axis differential detection capacitor is formed, and detection of an acceleration signal in the z-axis direction is realized.

Referring to fig. 6, a second embodiment of the MEMS triaxial accelerometer of the present invention is different from the first embodiment in the shape of the main mass block, and the main mass block 300 in the second embodiment is a bar shape with wider ends and thinner middle.

Although certain specific embodiments of the present invention have been described in detail by way of example, it should be understood by those skilled in the art that the foregoing examples are for purposes of illustration only and are not intended to limit the scope of the invention. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the invention. The scope of the invention is defined by the appended claims.

Claims (10)

1. A MEMS tri-axial accelerometer, comprising:

a substrate;

a torsional mass suspended above the substrate; the plane of the twisting mass block is an xy plane, wherein the positive direction of an x axis points to the right side of the xy plane, and the positive direction of a y axis points to the upper side of the xy plane;

the twisting mass block is of a central symmetry structure and comprises a main mass block (300), a first secondary mass block (100) positioned on the left side of the main mass block (300), a second secondary mass block (200) positioned on the right side of the main mass block (300), and first, second, third and fourth elastic connecting beams (301, 302, 303 and 304) parallel to a y axis;

the left/right edges of the first secondary mass (100) are connected with the main mass (300) through first elastic connecting beams (301), and the right/left edges of the second secondary mass (200) are connected with the main mass (300) through second elastic connecting beams (302); the center of the first secondary mass block (100) is connected to a first anchor point (501) of the substrate through a third elastic connecting beam (303), and the center of the second secondary mass block (200) is connected to a second anchor point (502) of the substrate through a fourth elastic connecting beam (304);

the first secondary mass block and the second secondary mass block (100 and 200) are respectively provided with a first movable electrode, a second movable electrode and a third movable electrode; the substrate is provided with a first fixed electrode, a second fixed electrode and a third fixed electrode which are used for respectively forming an x-axis detection capacitor, a y-axis detection capacitor and a z-axis detection capacitor with the first movable electrode, the second movable electrode and the third movable electrode.

2. The MEMS triaxial accelerometer of claim 1,

the z-axis detection capacitor is a flat capacitor, the third movable electrode is an upper electrode, and the third fixed electrode is a lower electrode; the number of the third movable electrodes is four, the three movable electrodes are respectively arranged at the left edge and the right edge of the first secondary mass block (100) and the second secondary mass block (200), the third fixed electrodes and the third movable electrodes are in one-to-one correspondence, and a first, a second, a third and a fourth z-axis detection capacitors are sequentially formed from left to right;

the first and fourth z-axis detection capacitors are connected in parallel to form a first group of z-axis detection capacitors, the second and third z-axis detection capacitors are connected in parallel to form a second group of z-axis detection capacitors, and the first group of z-axis detection capacitors and the second group of z-axis detection capacitors form a pair of z-axis differential detection capacitors.

3. The MEMS triaxial accelerometer of claim 1,

the left side and the right side of the first secondary mass block (100) and the second secondary mass block (200) are respectively provided with a third through hole (403); the first fixed electrode is positioned inside the third through hole (403), and the first movable electrode corresponding to the first fixed electrode is arranged on the side edge of the third through hole (403).

4. The MEMS triaxial accelerometer of claim 3,

two first fixed electrodes which are parallel left and right are arranged in each third through hole (403); the first movable electrode and the first fixed electrode are in one-to-one correspondence, and a first, a second, a third, a fourth, a fifth, a sixth, a seventh and an eighth x-axis detection capacitor are sequentially formed from left to right;

the first, third, fifth and seventh x-axis detection capacitors are connected in parallel to form a first group of x-axis detection capacitors, the second, fourth, sixth and eighth x-axis detection capacitors are connected in parallel to form a second group of x-axis detection capacitors, and the first group of x-axis detection capacitors and the second group of x-axis detection capacitors form a pair of differential capacitors.

5. The MEMS triaxial accelerometer of claim 1,

the upper side and the lower side of the first secondary mass block (100) and the second secondary mass block (200) are respectively provided with a fourth through hole (404); the second fixed electrode is positioned in the fourth through hole (404), and the second movable electrode corresponding to the second fixed electrode is arranged on the side edge of the fourth through hole (404).

6. The MEMS triaxial accelerometer of claim 5,

two second fixed electrodes which are parallel to each other at the left and the right are arranged in each fourth through hole (404); the second movable electrodes correspond to the second fixed electrodes one by one, so that a first y-axis detection capacitor and a second y-axis detection capacitor are sequentially formed on the upper side of the first secondary mass block (100) from left to right, a third y-axis detection capacitor and a fourth y-axis detection capacitor are sequentially formed on the lower side of the first mass block from left to right, a fifth y-axis detection capacitor and a sixth y-axis detection capacitor are sequentially formed on the upper side of the second secondary mass block (200) from left to right, and a seventh y-axis detection capacitor and an eighth y-axis detection capacitor are sequentially formed on the lower side of the second secondary mass block (200) from left to right;

the first, fourth, sixth and seventh y-axis detection capacitors are connected in parallel to form a first group of y-axis detection capacitors, the second, third, fifth and eighth y-axis detection capacitors are connected in parallel to form a second group of y-axis detection capacitors, and the first group of y-axis detection capacitors and the second group of y-axis detection capacitors form a pair of y-axis differential detection capacitors.

7. The MEMS triaxial accelerometer of claim 1,

a first through hole (401) is formed in the center of the first secondary mass block (100), and a second through hole (402) is formed in the center of the second secondary mass block (200); the third elastic connecting beam (303) is arranged in the first through hole (401), two ends of the third elastic connecting beam are connected to the side wall of the first through hole (401), and the center of the third elastic connecting beam is connected to a first anchor point (501) of the substrate; the fourth elastic connecting beam (304) is arranged inside the second through hole (402), two ends of the fourth elastic connecting beam are connected to the side wall of the second through hole (402), and the center of the fourth elastic connecting beam is connected to a second anchor point (502) of the substrate.

8. The MEMS triaxial accelerometer of claim 1,

the two ends of the first elastic connecting beam (301) are respectively connected with the main mass block (300), the middle of the first elastic connecting beam is connected with the primary mass block (100), the two ends of the second elastic connecting beam (302) are respectively connected with the main mass block (300), and the middle of the second elastic connecting beam is connected with the secondary mass block (200); or,

the two ends of the first elastic connecting beam (301) are respectively connected with the first secondary mass block (100), the middle of the first elastic connecting beam is connected with the main mass block (300), the two ends of the second elastic connecting beam (302) are respectively connected with the second secondary mass block (200), and the middle of the second elastic connecting beam is connected with the main mass block (300).

9. The MEMS triaxial accelerometer of claim 1,

fifth through holes (405) are respectively formed in the left side and the right side of the main mass block (300), the first secondary mass block (100) is located inside the left fifth through hole (405), and the second secondary mass block (200) is located inside the right fifth through hole (405).

10. The tri-axial accelerometer of any of claims 1-9,

the x-axis detection capacitor and the y-axis detection capacitor are comb-shaped capacitors.