CN1598597A - Single mass plate triaxial micro-mechanical accelerometer - Google Patents

Abstract

The invention discloses a three-axis micromechanical accelerometer with a single-mass flat plate. The mass flat plate is supported on a base by four sets of inner beams and four sets of outer beams. The comb-teeth intersections of the four electrodes on the substrate form four pairs of comb-teeth capacitors——capacitor C40a, capacitor C40b, capacitor C42a and capacitor C42b. Capacitor C42a and capacitor C42b are equivalent to capacitor Cx along the X direction, capacitor C40a and capacitor C40a. The capacitor C40b is equivalent to a capacitor Cy along the Y direction, and is characterized in that: it also includes a lower plate positioned under the quality plate, the quality plate and the lower plate form a parallel plate capacitor Cz, and the capacitor Cz forms together with the capacitor Cx and the capacitor Cy Three-axis accelerometer. The four sets of comb teeth of the mass plate, the four pairs of comb teeth fixed on the substrate and the lower plate are microfabricated on a chip. The advantage is that a mass plate is sensitive to linear accelerations in X, Y, and Z directions at the same time, and it is small in size and light in weight.

Description

Single-mass flat-panel triaxial micromachined accelerometer

technical field

The invention provides a single-mass flat-plate three-axis micro-mechanical accelerometer, which belongs to the technical field of micro-inertial devices.

Background technique

Refer to Figure 5. Said Emre Alper of Turkey's Middle East Technical University proposed a symmetrical structure at the Transducer 2001 conference to measure the angular velocity input around the Z axis, that is, the direction perpendicular to the mass plate. In this structure, the inertial mass slab is supported by four sets of inner beams and four sets of outer beams. Four groups of comb teeth protrude from the surroundings of the mass plate, which respectively intersect with comb teeth protruding from the four surrounding fixed electrodes to form four pairs of comb tooth capacitors. Its working principle is: the mass plate is subjected to electrostatic force in the XY plane, that is, the plane where the mass plate is located, and performs simple harmonic vibration along the X direction. At this time, if there is an angular velocity input around the Z direction perpendicular to the mass plate, due to the Coriolis effect, the mass plate will have a movement in the Y direction perpendicular to the XZ plane, thereby changing the formed between the mass plate and the corresponding fixed electrode. The size of the comb capacitor. The capacitance change includes the input angular velocity information, and the input angular velocity around the Z axis can be obtained by detecting and demodulating it.

The proposed structure is used to measure the angular velocity around the Z axis. However, in this structure, the four pairs of comb-teeth capacitors composed of the mass plate and the corresponding fixed electrodes are sensitive to the movement of the mass plate in the X and Y directions, and its structure can be used as a dual-column sensor that is sensitive to linear accelerations in the X and Y directions at the same time. axis accelerometer. But this structure cannot be sensitive to the linear acceleration in the Z direction.

Contents of the invention

The object of the present invention is to provide a single-mass flat three-axis micromachined accelerometer, which can be sensitive to the linear acceleration in the Z direction by adding an electrode plate under the mass flat plate, and at the same time sensitive to the linear acceleration in the X, Y, and Z directions.

The technical solution adopted by the present invention to solve the technical problem is: a single-mass flat three-axis micro-mechanical accelerometer, the mass flat is supported on the base by four sets of inner beams and four sets of outer beams, and the mass flat protrudes in four directions The four sets of comb teeth intersect with the comb teeth protruding from the four electrodes fixed on the substrate to form four pairs of comb capacitors - capacitor C40a, capacitor C40b, capacitor C42a and capacitor C42b, capacitor C42a and capacitor C42b, etc. The effect is a capacitor Cx along the X direction, and the capacitor C40a and the capacitor C40b are equivalent to a capacitor Cy along the Y direction. It is characterized in that: it also includes a lower plate positioned under the quality plate, and the quality plate and the lower plate form a parallel plate capacitor Cz, the capacitor Cz together with the capacitor Cx and the capacitor Cy constitute a three-axis accelerometer.

The four sets of comb teeth protruding from the quality plate in four directions, the four pairs of comb teeth fixed on the base and the lower pole plate are microfabricated on one chip.

The beneficial effect of the present invention is that a mass plate can simultaneously be sensitive to linear accelerations in three directions of X, Y, and Z, and a three-axis accelerometer of a single-mass plate can realize a three-axis accelerometer on a chip through microfabrication technology. , the alignment between the axes is guaranteed by the structural design, which avoids the assembly problem, and can reduce the volume and weight, and can reduce the area of the chip.

Description of drawings

Fig. 1 is a schematic top view of the structure of the present invention

Fig. 2 is A-A' sectional view of Fig. 1

Figure 3 is the equivalent electrical model of a single-mass flat plate in the XY plane

Figure 4 is the equivalent electrical model of a single-mass flat plate

Fig. 5 is a schematic diagram of Said's Z-axis gyro structure, which is a prior art diagram

In the figure: 18. base, 40a. fixed electrode I, 40b. fixed electrode II, 42a. fixed electrode III, 42b. fixed electrode IV, 41a. comb electrode I, 41b. comb electrode II, 41c. comb electrode III, 41d. Comb electrode IV, 44. Outer beam I in y direction, 45. Outer beam I in x direction, 46. Outer beam II in x direction, 47. Outer beam II in y direction, 48. Outer beam III in y direction, 49 .x-direction outer beam III, 50.x-direction outer beam IV, 51.y-direction outer beam IV, 52.x-direction inner beam I, 53.y-direction inner beam I, 54.y-direction inner beam II, 55.x Inner beam II in direction, 56. Inner beam III in x direction, 57. Inner beam III in y direction, 58. Inner beam IV in y direction, 59. Inner beam IV in x direction, 60. Mass plate, 61. Lower pole plate.

Detailed ways

Refer to Figures 1-4. The present invention adopts a symmetrical structure, and the mass plate 60 passes through the outer beam I44 in the y direction, the outer beam I45 in the x direction, the outer beam II46 in the x direction, the outer beam II47 in the y direction, the outer beam III in the 48.y direction, and the outer beam III in the x direction. III, 50. Outer beam IV in x direction, 51. Outer beam IV in y direction, 52. Inner beam I in x direction, I53 inner beam in y direction, II54 inner beam in y direction, II55 inner beam in x direction, III56 inner beam in x direction, The support beam composed of the inner beam III57 in the y direction, the inner beam IV58 in the y direction and the inner beam IV59 in the x direction is suspended and fixed to the base 18 . Four groups of comb teeth protrude from the surroundings of the quality plate 60: comb electrode I41a, comb electrode II41b, comb electrode III41c, and comb electrode IV41d, which are respectively connected to the fixed electrode I42a, the fixed electrode II40a, the fixed electrode III42b, and the fixed electrode IV40b. The protruding comb teeth intersect to form four pairs of comb-teeth capacitors C40a, C40b, C42a, C42b as shown in FIG. 3 . At the same time, the mass plate 60 and the lower pole plate 61 form a parallel plate capacitor Cz as shown in FIG. 4 .

When the mass plate 60 is subjected to the inertial force in the X direction, the outer beam I44 in the y direction, the outer beam II47 in the y direction, the outer beam III48 in the y direction, the outer beam IV51 in the y direction, the inner beam I53 in the y direction, the inner beam II54 in the y direction, and the The inner beam III57 in the direction and the inner beam IV58 in the y direction are bent in the XY plane. For the outer beam I45 in the x direction, the outer beam II46 in the x direction, the outer beam III49 in the x direction and the outer beam IV50 in the x direction, the change of the comb tooth capacitors C40a and C40b in the X direction is a compression rod, and the stiffness is very large, thus limiting the comb teeth Capacitors C40a, C40b change in the X direction. At the same time, because the mass plate 60 is not subjected to the component force in the Y direction, the comb-teeth capacitors C40a and C40b are not displaced in the Y direction. The outer beam I44 in the y direction, the outer beam II47 in the y direction, the outer beam III48 in the y direction, and the outer beam IV51 in the y direction are pressure bars for the changes of the comb tooth capacitors C42a and C42b in the Y direction, and the rigidity is very large. Therefore, only the comb capacitors C42a, C42b are displaced in the X direction. The acceleration component in the X direction can be obtained through the change of the sensitive comb capacitors C42a and C42b in the X direction.

Similarly, when the mass plate 60 is subjected to the inertial force in the Y direction, the outer beam I45 in the x direction, the outer beam II46 in the x direction, the outer beam III49 in the x direction and the IV50 outer beam in the x direction, and the four inner beams I52, The x-direction inner beam II55, the x-direction inner beam III56, and the x-direction inner beam IV59 are bent in the XY plane. The outer beam I44 in the y direction, the outer beam II47 in the y direction, the outer beam III48 in the y direction, and the outer beam IV51 in the y direction limit the displacement of the comb tooth capacitors C42a and C42b in the Y direction. The outer beam I45 in the x direction, the outer beam II46 in the x direction, the outer beam III49 in the x direction and the outer beam N50 in the x direction limit the displacement of the comb-tooth capacitors C40a and C40b in the X direction, so that only the comb-tooth capacitors C40a and C40b are in the Y direction There are changes. By being sensitive to this change, the acceleration component in the Y direction can be obtained.

When the mass plate 60 is subjected to an inertial force in the Z direction, all the outer and inner beams bend in a direction perpendicular to the XY plane. And the degree of freedom of the mass plate in the plane direction is limited by the inner beam and the outer beam due to compression. Thus only the comb capacitor Cz changes in the Z direction. By being sensitive to the change of the capacitance, the acceleration component in the Z direction can be obtained.

Claims (2)

1, dull and stereotyped three micro-mechanical accelerometers of a kind of simple substance amount, the quality flat board is supported in the substrate by four groups of inner beams and four groups of outer beams, four groups of broach that the quality flat board stretches out to four direction, respectively be fixed on the broach that stretches out on suprabasil four electrodes and intersect and constituted four pairs of broach capacitors---capacitor C40a, capacitor C40b, capacitor C42a and capacitor C42b, capacitor C42a and capacitor C42b equivalence are the capacitor Cx along directions X, capacitor C40a and capacitor C40b equivalence are the capacitor Cy along the Y direction, it is characterized in that: also comprise a bottom crown that is positioned at below the quality flat board, quality is dull and stereotyped to constitute plane-parallel capacitor Cz, capacitor Cz and capacitor Cx with bottom crown, capacitor Cy constitutes three axis accelerometer together.

2, single mass three-shaft micro-mechanical accelerometer according to claim 1, it is characterized in that: four groups of broach that described quality flat board stretches out to four direction be fixed on suprabasil four pairs of broach and bottom crown, by microfabrication on a chip.

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