FR2685579A1 - Anti-radiating monopode resonator - Google Patents

Abstract

The invention relates to a resonator consisting of a piezoelectric crystal linked to the base of a housing by means of a single fixing occupying a narrow region of the periphery of the crystal, and kept at a constant temperature by virtue of a heating element arranged close to the fixing. The mechanical stresses applied to the housing are not transmitted to the piezoelectric crystal due to the principle of the fixing. Moreover, specific insulation of the crystal forces the thermal exchanges to take place solely through the fixing for holding the crystal, to the exclusion of any other path. This single passage for the thermal flux is regulated in terms of temperature by a temperature sensor placed in thermal contact with the fixing for holding the crystal. The crystal (10) covered with a metallic layer (11) is linked to the base (31) of the housing (30) by a narrow foot (20) equipped with a heating means (22) and with a temperature sensor (21). The housing is evacuated and the electrical supplies are effected by means of sealed passages (32 to 37). The device according to the invention is particularly intended for producing stable frequency references, of low consumption and insensitive to the effects of the environment (on-board avionic and spatial references).

Description

ANOPRAYONING MONOPODE RESONATOR
The present invention relates to a piezoelectric resonator comprising a sealed case of its atmosphere, the internal wall of which is polished and covered with a layer and, inside this case, a piezoelectric crystal in the shape of a disc, heated , the temperature of said crystal being able to change independently of that of the case, the heating of the crystal, being carried out by conduction, to the exclusion of any heat exchange effected by radiation or by convection, by means of a heating element located at the crystal holding fastener, which is characterized by the fact that it is unique and located in a narrow zone of the periphery of the crystal, which has the particularity of being covered with a thin layer of an anti-radiating metal at the except for the edge of the disc, the metallization of the faces forming the two excitation electrodes of the piezoelectric crystal and at the same time forming a screen preventing haunt the heat exchanges by radiation between the crystal and its case, the temperature regulation of the crystal being ensured by means of a temperature sensor placed at the limit of the piezoelectric disc and of its holding fixture.

Since the resonant frequencies of a piezoelectric crystal are very sensitive to temperature, all quality oscillators use a thermostatically controlled crystal. The crystal is generally mounted in a sealed box, empty or filled with a dry gas, which is itself placed inside an oven comprising a heating resistor or a power transistor and a heat-conducting enclosure. The whole is isolated from the outside by polyurethane or equivalent foam, or by a Dewar vase. The oven temperature is continuously regulated by a temperature sensor with reference to a set voltage. This type of thermostat gives good results in frequency stability. However, it has the drawback of being bulky, heavy, consuming energy and being long enough to heat up. It is indeed difficult to obtain correct operation of the oscillator in less than a quarter of an hour after powering up. The power required commonly reaches 15 watts during the start-up period and then stabilizes at around 2 or 3 watts, depending on the outside temperature (around 3 watts at -50 "C and 2 watts at +25" C ).

To remedy some of these drawbacks, it has been proposed in particular in the patent for
United States of America No. 3,431,392, to heat the resonator by resistive layers deposited directly on the piezoelectric crystal. The layers are for example nichrome, tantalum, or any other resistive metal.

U.S. Patents 3,201,621, 3,715,563 and 3,818,254 use the same principle of resistive layers deposited on the periphery of the crystal in a horseshoe shape.

The disadvantage of this type of solution is that the heating of the crystal is inhomogeneous and that the thermal gradients which result from it create a set of thermomechanical constraints which is at the origin of a variation of the resonance frequency of the crystalline plate constituting the resonator, in turn causing a frequency variation of the oscillator.

It has also been proposed in French patent No. 1,438,172 and in United States patents No. 2969471 and 3 121153 to heat the piezoelectric crystal by radiant energy using heating resistors arranged between the crystal. and concave reflectors. The author himself proposed in the French patent n ° 83 C7307 to use low-voltage incandescent bulbs to carry out heating by infrared radiation.

Radiant heating has the advantage of being homogeneous, but it has the disadvantage of introducing a time constant which cannot be canceled due to the radiation resistance which exists between the radiant elements and the resonant crystal.

Furthermore, in the various solutions already proposed, the heat exchanges between the crystal and the heat source are not channeled by a single passage but use various channels by conduction and (or) by radiation. These solutions therefore do not make it possible to avoid the thermal gradients at the level of the crystal; hence the appearance of a dynamic temperature effect linked to the temporal evolution of these gradients when there is a change in the external temperature conditions.

The object of the present invention is to remedy the aforementioned drawbacks by heating the crystal by solid conduction only by means of a heating element located at the level of the fixing for holding the crystal, a single fixing situated in a narrow zone on the periphery of the latter. ci (monopod resonator). Since the retaining attachment is unique, the crystal expansions do not cause any thermomechanical stress (free dilation), therefore no variation in frequency of the oscillator. To force the heat exchanges to take place only by solid conduction by the crystal retaining fixing, the heat exchanges by radiation are canceled which normally are established between the crystal and its case by completely covering the crystal and the interior of the housing of a reflective layer thus constituting a double anti-radiating screen. Only the edge of the crystal is not covered, the discontinuity thus created allowing the two metallized faces of the crystal to be brought to different electrical potentials and therefore to be able to serve as excitation electrodes for the piezoelectric crystal. The electrical connections of these electrodes are made in a very thin wire and not very conductive of heat so as to make negligible the heat exchanges which could be established by solid conduction through the connections. The case containing the crystal is completely emptied, the residual gas pressure being less than 10 Smbar: heat exchanges by gas convection are thus made impossible. Under these conditions, the heat exchanges between the crystal and the heat source can only be established by the retaining fixing of the crystal, to the exclusion of any other channel. A single and forced passage of the heat flux is thus produced, the temperature of which passage can be strictly controlled by the use of a temperature sensor placed at the common border between the active part of the crystal and its retaining attachment, and in good thermal contact with the latter. Said temperature sensor can be easily compared to a reference setpoint and control, by a regulation loop, the heat source placed at the level of the binding, thus determining in a stable and precise manner the temperature of the forced passage of the heat flow.

The invention thus provides the double advantage of a homogeneous temperature crystal (absence of thermal gradients) and stable (control of the temperature of the required passage). The invention also aims to reduce the volume and the mass of the oscillator to piezoelectric crystal, to reduce energy consumption and reduce the warm-up time when starting the oscillator.

These aims are achieved by means of a resonator of the type defined at the head of the description, in which the crystal has for example the shape of a monopod disc, the disc constituting the resonant part proper and the foot constituting the single fixing for maintaining the resonant part, the heat source being for example made of a resistive heating wire wound on the foot, the temperature sensor being for example a thermistor bonded to the limit of the disc and the foot. The anti-radiating metal layer covering the two faces of the disc and the inside of the case is advantageously produced by depositing a gold film of approximately 1000 Angstroms thick while the electrical connections of the electrodes are advantageously made using nichrome wires with a diameter of 5/100 mm.

According to a variant of this embodiment, two metallic screens, thin, reflective, close to the crystal disc and located opposite it, limit even more effectively the heat exchanges by radiation between the crystal and its case by reflecting in particular the radiation emitted by the edge of the crystal. These two screens are fixed, for example glued, on the base of the crystal and therefore also heated by the heating element placed in the same place. Their temperature which is regulated by the temperature sensor fixed at the limit of the disc is therefore very substantially identical to that of the resonant crystal, thus reducing to zero the balance of heat exchanges by radiation between themselves and the resonant part of the crystal.

One of the screens has a disc shape identical to that of the resonant part of the crystal, the other screen has the shape of a box whose bottom looks at the crystal disc and whose edge surrounds the edge of the crystal.

According to this latter embodiment, the two reflective screens, close to the crystal disc and located opposite the latter may advantageously consist of the two electro-metals of a piezoelectric resonator with non-adherent electrodes, the resonant part of the crystal remaining naked, that is to say not covered with metal electrodes and the excitation of the piezoelectric crystal being produced by an electric voltage applied between the non-adherent electrodes also serving here as reflective screens. As in the previous embodiment, the crystal-non-adherent electrode assembly has a single holding attachment on which the heating element and the temperature sensor are arranged. The external faces of the electrode holder as well as their edge and that of the resonant crystal are covered with a thin anti-radiating layer in order to limit the heat exchanges between the case and the assembly thus formed. The piezoelectric resonators with non-adherent electrodes which can be used according to this latter embodiment of the invention are in particular those described in French patents n "76 010 35, 76 162 89, 77 173 09, 78 022 61, 79 18 553, 8509097 and 88 14197.

Other characteristics and advantages will emerge from the description which follows of particular embodiments of the invention, with reference to the appended drawings, in which:
- Figure 1 shows schematically a thermostated resonator according to a
first embodiment of the invention,
- Figure 2 shows schematically a thermostated resonator according to a
variant of the embodiment of the invention shown in FIG. 1,
- Figure 3 is a diameter section perpendicular to the plane of the crystal of a res
thermostatically controlled swimming pool with reflective metal screens,
- Figure 4 is a diametrical section perpendicular to the plane of the crystal of a reso
non-stick electrodes thermostatically controlled according to the principles above
exposed
We see in Figure 1 a first embodiment of a thermostated resonator according to the invention comprising a sealed housing composed of a base 31 and a cover 30 sealed on the base 31. The internal face of the cover 30 is coated with a thin film of gold 38 making it reflective to thermal radiation. Inside the case is mounted a piezoelectric crystal in the form of a monopod disc consisting of a disc 10 and a foot 20 on which is wound a resistive heating wire 22 whose ends are connected to terminals 34, 35 which pass through in a sealed and electrically isolated manner the base 31 of the case. A temperature sensor 21 connected to the terminals 33, 36 of the base 31 is bonded in the connection area of the disc and of the base and controls the temperature of the thermal passage located between the disc 10 and the wound wire 22. The disc 10 is covered, on both sides, with a thin deposit of gold 11, its edge 12 being left bare. The metallized faces 11 of the disc 10 are connected by electrical conductors 13, 14 to the terminals 32, 37 of the base 31 thus allowing the electrical excitation of the piezoelectric crystal. The connections of the conductors 13, 14 to the metallized faces 11 are close to the sensor 21.

FIG. 2 shows a variant of the previous embodiment, a variant in which the base of the piezoelectric crystal is replaced by a small incandescent bulb 23, the connection between the crystal disc 10 and the bulb 23 being produced by means of 'a thermistor 21 bonded between the disc 10 and the bulb 23. The supply wires 24, 25 of the bulb 23 are connected to the terminals 34 and 35 of the base 31. The glass envelope of the bulb 23 is metallized by a metallic deposit or by a strip of aluminum foil stuck directly on the glass. The incandescent bulb 23 of FIG. 2 can be replaced by a heating transistor. An additional isolated electrical bushing is then necessary on the base 31 for the electrical supply of the base of the transistor.

There is shown in Figure 3 a section of a thermostated resonator according to another embodiment of the invention and comprising, inside a housing not shown, a monopod piezoelectric crystal (disc 10, foot 20) covered, except for section 12, a thin deposit of gold 11 serving as an anti-radiating layer and excitation electrodes for the piezoelectric crystal and the faces of which look at two reflective metal screens 41 and 42 fixed to the base 20 of the crystal , the screen 41 having the shape of a disc identical to the disc 10 and the screen 42 having the shape of a box whose edge 43 reflects the thermal radiation emitted by the edge 12 of the resonant crystal. The heating means 22 and the temperature measurement 21 are identical to the previous ones already described.

FIG. 4 shows a variant of the previous embodiment, a variant in which the role of the reflectors 41, 42 of FIG. 3 is played by the electrodes 53, 54 of a piezoelectric crystal 10 with non-adherent electrodes, the electrode holders 51, 52 themselves being covered with a thin layer of gold on their external faces 55, 56 as well as on their edges 57, 58.

Unlike the previous embodiment, the faces of the disc 10 are bare, as is the rule in the case of a resonator with non-adherent electrodes, while the edge 12 of the disc 10 and covered with a thin film d gold serving as an anti-radiant screen. The assembly is monopod (foot 20) and the means for holding the electrode holders 51, 52 are the means usually used in the case of resonators with non-adherent electrodes, in particular the calibrated collets one of which is shown on the figure (clip 60). The only difference compared to the previous state of the art, all the pliers of the set of pliers used are here covered with a thin film of anti-radiating gold. Again, the heating means 22 and the temperature measurement 21 are identical to the previous ones already described.

Claims (6)

 1) Anti-radiating monopod resonator, including a waterproof case and, inside  laughter of this case, a piezoelectric crystal having an active central part  10, on the opposite faces of which a thin metallic layer 11 is deposited,  and a peripheral holding part 20; means of support for the part pe  device 20 for holding the crystal inside the case; heating means  fage by solid conduction 22; at least one temperature sensor 21; of  reflectors 41, 42, 53, 54, to prevent the heat radiated by the crystal from being  transmitted to the housing; means for fixing the reflectors; and drivers  electrical connections between on the one hand the thin metallic layer 11, the means  solid conduction heating 22, the temperature sensor 21, and secondly,  terminals 32 to 37 of electrical connections which pass through the base 31 of the  sealed housing, characterized in that the thin metallic layer 11 re  covers the entire surface of the piezoelectric crystal except for section 12 and  serves on the one hand as an excitation electrode of the active central part 10 and on the other hand  an anti-radiant layer preventing the crystal from radiating its heat; in that  the interior of the waterproof case containing the crystal is itself covered with a neck  reflective che; in that the peripheral part 20 for holding the crystal is  formed of a single leg connecting the active central part 10 to the base 31 of the housing  ; in that the temperature sensor is positioned at the common border of the  active part 10 and foot 20 and in good thermal contact with the latter; and in this  that the solid conduction heating means 22 are fixed in good contact  thermal on the foot 20 or even constitute the foot 20 itself.  2) Resonator according to claim 1, characterized in that the heating means  fage by solid conduction 22 consist of a resistive heating wire wound on  foot 20.  3) Resonator according to claim 1, characterized in that the means for  solid conduction heating 22 are provided by a small incense bulb 23 which at the same time constitutes the single base 20 connecting the active central part 10 to the base 31 of the housing. 4) Resonator according to claim 1, characterized in that the heating means by solid conduction 22 are provided by a heating transistor which at the same time constitutes the single foot 20 connecting the active central part 10 to the base 31 of the housing . 5) Resonator according to any one of claims 1 to 4, characterized in that two reflective metal screens 41, 42 fixed on the single leg 20 are arranged at a short distance and opposite the opposite faces of the active central part 10, completely surrounding it and in particular its edge 12. 6) Resonator according to claim 5, characterized in that the two reflecting screens 41, 42 consist of two metal electrodes 53, 54 of a piezoelectric resonator with non-adherent electrodes, the active central part 10 of the crystal being naked, the doors -electrodes 51, 52 being covered with an anti-radiating layer on their external faces 55, 56 as well as on their edges 57, 58 the edge 12 of the piezoelectric crystal also being covered with the same anti-radiating layer.