NAVIGATION INSTRUMENTS

THERMOELASTIC LOSSES IN STRUCTURAL MATERIALS

OF WAVE SOLID-STATE GYROSCOPE RESONATORS

B.S. Lunin

,

A.V. Yurin

,

M.A. Basarab

,

V.A. Matveev

,

E.A. Chumankin

Bauman Moscow State Technical University, Moscow, Russian Federation

e-mail:

bmic@mail.ru

One of the key features of the resonators of wave solid-state gyros is their quality

factor defining in many respects the instrument’s systematic and random errors. To

enhance the resonator quality, it is necessary to take into consideration peculiar

properties of different dissipative processes in design process. The contribution of

these processes depends on the resonator material behaviour, its design, its surface

processing quality, vacuum level in the instrument. Thermoelastic internal friction is

a fundamental dissipative process. The influence of internal thermoelastic friction on

the characteristics of resonators made of various materials is revealed by means of a

thermoelastic processes model and finite-element simulation. It is shown that internal

thermoelastic friction in quartz glass is very small as compared to other structural

materials. It permits to recommend quartz glass as a main structural material for

wave solid-state gyroscope resonators.

Keywords

:

wave solid-state gyroscope, resonator quality factor, thermoelastic losses,

finite-element simulation.

In the last decade, vibratory giroscopes have become widespread, their

operation based on Сoriolis effect. The centerpieces of these instruments are

mechanical resonators of various design — frame, ring, hemispherical, etc.

[1, 2]. One of the main features of these resonators is their quality factor,

which to a large degree determines the instrument’s systematic and random

errors [2]. To enhance the quality factor, materials with small thermoelastic

internal friction are usually selected as structural materials: quartz glass,

silicon, metals, synthetic sapphire, etc. To achieve the best results in the

resonator design, one should take into consideration specific features of all

dissipative processes. It will be recalled that the internal friction in a solid

body is the whole set of all irreversible thermodynamic processes resulting

in energy dissipation of resonator’s elastic vibrations. The value of internal

friction is proportional to the ratio of energy dissipated for one period of

vibrations (

Δ

W

), to the total resonator’s energy (

W

):

ς

= Δ

W/

(2

πW

)

,

(1)

here the resonator’s quality factor is

Q

=

ς

−

1

.

As the internal friction in the resonator is determined with the sum of

all dissipative processes, then

ς

=

ς

T

+

ς

V

+

ς

S

+

ς

G

+

. . . ,

(2)

28

ISSN 0236-3933. HERALD of the BMSTU. Series Instrument Engineering. 2015. No. 2