FR2695284A1 - Tonpilz transducer protected against shocks. - Google Patents

Abstract

The invention relates to transducers of the Tonpilz type protected against shocks. It consists in placing between the countermass (603) and the housing (607) of a known Tonpilz transducer, a sheath (609) which adheres to these two organs. This sheath is made of a material whose stiffness increases with the frequency of the stresses applied to it. This material can for example be a known polyurethane. For low frequency vibrations, the sheath does not slow down the movement of the countermass relative to the housing. For high-frequency vibrations, characteristic of a shock, the sheath slows down these movements and prevents too much stress on the piezoelectric motor (602) of the transducer, more particularly in traction. It makes it possible to protect the Tonpilz transducers carried by a vehicle dropped from an aircraft against shocks.

Description

Tonpilz Transducer Protected Against Shocks The present invention is

relates to transducers

  electroacoustics of the Tonpilz type, which are mainly used

  In underwater acoustics, it is desired to protect against the shocks that occur when the vehicle on which these transducers are mounted hits the water with violence, for example because it is dropped from an air vehicle. Tonpilz transducers are known for example from French Patent No. 2,290,810 filed November 8, 1974 by the Applicant They comprise, as shown in Figure 1 attached, a transmitter horn 101 excited by an engine

  piezoelectric device 102 formed of a stack of ceramic rings

  that piezoelectric, which comes to rely on a counter-

  103 The ceramic rings are subject to a precautionary

  Stroke obtained by connecting the flag to the counterpart by a threaded rod 104, fixed on one side to the flag and passing through the counterweight A nut 105 is screwed on this threaded rod to bear against the counterweight By screwing this nut, we bring the countering the flag, which requires pressure

the ceramic rings.

  In order to be able to emit several distinct frequencies,

  as well as modulated frequencies intended to obtain a

  By compression of pulses, one is led to use a flag whose section is much larger than that of the ceramic rings. The pressure exerted on these rings

  is therefore equal to the hydrostatic pressure on the roof, multi-

  folded by the ratio between the section of this flag and that of the rings To make the ceramic rings insensitive to stress from this hydrostatic pressure, the patent cited above recommends suspending the transducer by its flag using a compliant cylinder 106 which on one side comes to bear on the housing 107 of the transducer and the other

  side supports the pavilion The nature and structure of this cylinder

  The casing 107 is itself supported by the structure 108 of the vehicle to which the transducer is attached. The countermass 103, which is housed for the most part in the central cavity of the casing 107, is thus free of its movements in this cavity which makes it possible to obtain the insensitivity of the ceramic rings to the constraints

  from the hydrostatic pressure.

  The freedom of this mass therefore allows it to advance or retreat in a movement parallel to the axis of the transducer, this axis being materialized by the threaded rod 104 This result, which provides the desired effects vis-à-vis the pressure hydrostatic, has disadvantages vis-à-vis the movements induced by

  Indeed, during these shocks, the counter-shock

  mass, which has a significantly greater inertia than the flag (this allows the transducer to operate), has a greater deflection than that of the flag The differential movement between the flag and the counterweight resulting resulting in efforts to additional compression and traction on the motor 102 The limits of the constraints

  that can be applied to the ceramic rings are con-

  and calculations, as well as experience, show that, for

  a vertical shock in the water at a speed of 50 meters per

  the compression stress is less than the static limit

  only in a ratio 2, while the tensile stress is greater than the static limit in a ratio 5 This result is not surprising since, as we know, ceramics

  are much more resistant in compression than in traction.

  FIG. 2 shows the excitation resulting from the shock and the return force on the ceramics as a function of the

  time, and in Figure 3 the absolute displacement of the counter-

  mass and flag, always as a function of time, for a transducer protected against the hydrostatic pressure of the

  as shown in FIG. 1 (front support).

  By way of comparison, FIGS. 4 and 5 show the same parameters for a transducer which would be fixed

  on the structure 108 directly by its counter-support

  but which of course would not be protected against the hydrostatic pressure It is quite clear, when comparing these curves, that the transducer fixed by its horn is weakened with respect to the shocks To prevent the counterweight from backing off too much far away from the pavilion, resulting in the excessive tensile stresses seen above, one could think of using a stop which would limit the rearward movements of this countermass This system would be effective, but would have the disadvantage of limiting the protection of the transducer screws -a-vis

  hydrostatic stresses for the most important pressures

  those precisely where this protection is most needed.

  In addition, it would be necessary to provide for mechanical tolerances

  very strict rules on the games between the different components

of the transducer.

  To overcome these disadvantages, the invention proposes a

  transducer according to claim 1.

  Other features and advantages of the invention appear

  clearly in the following description, presented as a

  non-limiting example with reference to the accompanying figures which show Figure 1, a sectional view of a Tonpilz transducer according to the prior art;

  FIGS. 2 and 3, force and displacement curves

  parts of the transducer of Figure 1; Figures 4 and 5, the same curves as those of Figures 2 and 3, but for a transducer operating in rear support;

  FIG. 6, a section of a transducer according to the invention

  tion; FIG. 7, a curve of the shear modulus in

  frequency function for a material used in the trans-

  driver of Figure 6; Figures 8 and 9, the same curves as those of Figures 2 to 5, but for a transducer according to the invention;

  FIGS. 10 and 11, sensitivity curves for accelerating

  ration as a function of frequency, respectively for a trans-

  known conductor and for a transducer according to the invention; and FIGS. 12 and 13, partial sections of front and top of the transducer according to the invention of FIG. 6. The transducer according to the invention shown in section in FIG. 6 comprises, as in the prior art, a flag 601, a motor 602 formed of ceramic rings

  piezoelectric device, a counterweight 603, a threaded rod of

  604, a clamping nut 605, a cylinder 606 forming a mechanical filter and a housing 607 fixed to the structures 608 of the

carrier vehicle.

  According to the invention, a cylindrical sheath 609 has been placed between the counterweight 603 and the housing 607, which adheres by its inner wall to the counterweight and by its outer wall on the outside.

inside of the case.

  This sheath is made of a compliant material which works in bending to slow down the longitudinal movements of the counterweight relative to the housing. This makes it possible to reduce the tensile stresses notably applied to the piezoelectric motor 602 during longitudinal shocks to the transducer.

  To maintain protection against the effects of pressure

  hydrostatic flow and not to disturb the acoustic function of the transducer, while protecting the piezoelectric motor from

  this one against the forces due to violent and brief shocks, the in-

  vention further proposes that the sheath 609 be made in a

  particular material whose characteristics, more particularly

  Stiffness changes with the frequency of the stresses applied to it. Such materials, such as polyurethanes, which have such variations in their characteristics, and which are in a way

  for low frequency and hard solicitations for

  Such a material is, for example, de-

  written in the French patent 2,672,179 filed by the Application-

published on 25 January 1991.

  FIG. 7 shows the shear modulus G

  depending on the frequency of this material We see that this

  dule evolves very quickly depending on this frequency. The shape of this curve is variable depending on the composition of the polyurethane chosen and it is quite easy to obtain the desired characteristics by varying in a known manner this composition This allows to adapt the characteristics of this sheath, which forms a filter acting in shear, to the characteristics of the cylinder 606, which forms a filter acting in compression, as well as the characteristics of the piezoelectric motor.

  In a practical implementation, the various parameters

  meters to get in dynamics a stiffness in shear of

  sheath 609 substantially equal to 1.5 times the stiffness in compres-

  of the cylinder 606, and substantially equal to 0.4 times the stiffness

  in compression of the piezoelectric motor

  the stiffness of the sheath is then substantially equal to 0.2 times

  the stiffness of the cylinder and 0.1 times the stiffness of the engine.

  So in static, that is to say outside shocks

  longitudinal, the counterweight is free from the housing.

  This makes it possible to avoid problems with the hydraulic pressure.

  static, which increases very slowly as the immersion of the carrier vehicle of the transducer increases, and

  do not disturb the acoustic operation of the transducer.

  In dynamic against, that is to say under the effect of a sudden shock corresponding to a significant acceleration of the counterweight to the housing, the sheath strongly solidarise the counterweight and the housing, thus braking the movement of this countermeasures and thus limiting the efforts applied on the

  engine, more particularly traction forces.

  FIGS. 8 and 9 show the variations of the same parameters as those of FIGS. 2/3 and 4/5, but in the case of a transducer according to the invention the curves borne by

  these figures bring out in a particularly spectacular way

  the improvement obtained with the invention.

  In addition, to verify the effect of the invention on the sensitivity

  The microphones of the transducer have been plotted for the curves of this sensitivity Sg as a function of the frequency, respectively for a transducer according to the prior art such as that of FIG. 1 and for a transducer according to the invention such as that of FIG. are appended in Figures 10 and 11 and

  it can be seen that the alteration of the sensitivity is extremely

  is weak and appears only slightly in high frequency, which is normal considering the frequency response of the material. In addition, the invention has another advantage in the case of shocks that are not only longitudinal, which is common since it is not at all obvious that the impact of a carrier vehicle dropped from an aircraft on the sea surface is strictly along the axis of the transducers, which may themselves themselves be more or less off-axis with respect to the axis of the carrier vehicle In these conditions, side impacts tend to cause a lateral displacement of the countermeasures by causing a bending of the threaded rod and bending stresses of the piezoelectric motor. It is known that such bending stresses, corresponding on one side to a

  compression and the other side to a pull are particularly-

  harmful to the ceramics with which this engine is built. Or precisely the sheath 609 tends to slow the pendulum movement of the counterweight relative to the housing, and thus the torsion of the threaded rod and the piezoelectric motor This effect is even more pronounced, as in this sense, the section of the subject material the efforts, compression and traction in

  this case is particularly large.

  and almost a lateral blocking of this counterweight, which is particularly favorable to the engine

piezoelectric.

  This sheath can be manufactured and put in place

  According to a preferred embodiment, the polyurethane material subjected to a temperature where it is substantially liquid, for example of the order of 80.degree. C., is cast in a thin ring 610 forming a lost mold, as shown in FIGS.

  FIGS. 12 and 13 During this operation, passengers will be

  longitudinal grooves 611 between the counterweight 603 and the sheath 609, for example by placing against the counterweight slightly flattened tubes against the counterweight These passages will be used to pass the motor supply son, which previously could pass freely between the counter and the case. After cooling, the counterweight provided with its sheath is pressed, and the molding ring which remains in place in the housing 607, with the aid of a press, for example. To obtain a correct positioning of this assembly, it is possible to arrange a shoulder 612 on the inside of the housing, in order to stop the counterweight in its downward movement under the action of the press If the tightening obtained is not enough, because your tone did not want to be brought for example to press too hard on the set to put it in place, we can stick the ring

  in the housing with an adhesive resistant to the conditions of

  use of the transducer, of the acrylonitrile type, for example.

  The invention therefore makes it possible to obtain a transducer of the type

  Tonpilz, which is protected against the effects of

  hydrostatic pressure, only against the effects of shocks

  example, the release of the carrier vehicle of this transducer

  then an aircraft, which nevertheless retains excellent

acoustic properties.

Claims (1)

1 Tonpilz transducer protected against shocks, of the type comprising a horn (601), a counterweight (603), a piezoelectric motor (602) placed between the horn and the counterweight, a threaded rod (604) connecting the horn and the counterweight for compressing the piezoelectric motor between these two members, a housing (607) surrounding the counterweight, and a compliant cylinder (606) for suspending the horn from the housing, characterized in that it further comprises resilient connecting means (609) connecting the counterweight to the case; these means being made of a material whose stiffness increases with the frequency of the stresses applied to it due to the movement of the counterweight relative to the housing. Transducer according to claim 1, characterized in that this material is a polyurethane. 3 transducer according to any one of claims 1 and 2, characterized in that the stiffness of the connecting means is substantially multiplied by 7.5 between a quasi-static bias and a dynamic bias. Transducer according to any one of the claims   1 to 3, characterized in that the connecting means are in the form of a cylindrical sheath (609) inserted between the countermass   and the housing and adhering to the walls of these two bodies.   Transducer according to claim 4, characterized in that it further comprises a thin ring (610) surrounding the sheath (609) and forming lost form for the design of the sheath by casting a substantially liquid material which then hardens. 6 transducer according to claim 5, characterized in that it further comprises at least one longitudinal channel located between the wall of the counterweight (603) and the sheath (610) to allow passage of the motor supply son piezoelectric (602).