DE537199C - Temperature compensated socket for piezo crystals - Google Patents

Description

The present invention relates to a temperature-compensated version for piezo plastics, in which the crystal while maintaining an air layer of constant thickness between two Plate electrodes is supported. It is known that changes in temperature cause the Socket and the crystal itself corresponding changes in the width of the air gap between the crystal and the electrodes, which changes the frequency of the crystal. It has therefore been proposed to adjust the distance between the electrodes in a predetermined manner to change with the temperature in such a way that the width of the air gap remains constant.

According to the present invention, the temperature-dependent regulation of the electrode spacing is performed achieved in a simple manner that the plate electrodes by primary spacers made of the same material and same thickness as the crystal and secondary spacers made of material of suitable material Temperature coefficient, preferably coefficient zero, and the thickness of the desired Keep the air layer at a distance. Purpose-

In general, normal spacers are used, which can be used to give the air gap a predetermined size.
The socket according to the invention is shown in the drawing in two projections.

For the sake of clarity, the distance between the crystal and the electrodes is drawn exaggerated and the connections are omitted.

The socket 10 consists of a lower plate and an upper plate 12, expediently made of a bronze alloy. Between the plates there is an intermediate piece 13, either in the form of a ring surrounding the crystal 14 or consisting of several individual parts; the plates 11 and 12 are separated from one another by this intermediate piece. This primary intermediate piece consists of the same material as the crystal itself and has the same strength, and in fact it consists expediently of pieces or corners of the actual crystal, which are cut off from this after the crystal has been cut. The screws 15 pass through the upper electrode 12, and are screwed into the lower electrode 11 at 16, the electrode 12 with holes ^lt I2 is provided for the screws. The electrode 12 is pressed firmly against secondary intermediate pieces 19 by spiral springs 17, which are located between the screw heads 15 and insulating sleeves 18, which, roughly similar to the primary intermediate pieces 13, can be ring-shaped or designed in some other way. They have a thermal expansion coefficient of zero, such as Invar, and have a normal

thickness of about 0.025 ° of ° »° 5 n ™ ¹ . J ^e
the size of the desired air gap.

According to the invention, a complete set of such disks or rings 19 is kept in stock, of which each ring or disk has a predetermined normal thickness and each differs from the others in terms of thickness by a predetermined normal dimension. Since these secondary intermediate pieces are easily exchangeable, the desired size of the air gap can easily be set by inserting a specific intermediate piece.
Since the piezo material and the primary spacers have the same temperature coefficient, changes in temperature of the primary spacers do not affect the gap width. Furthermore, since the secondary spacers have a coefficient of expansion of zero, the air gap remains constant even when the temperature of the mount changes.

If piezo materials other than quartz are used, the primary spacers must can of course also be made from this material. If you go for the air distance desires a coefficient other than zero, one must have secondary spacers from the use the desired coefficient.

Claims (3)

Patent claims: 1. Temperature-compensated version for piezo crystals, in which the crystal is under Maintaining an air layer of constant thickness held between two plate electrodes is, characterized in that the plate electrodes by spacers from the same Material and of the same thickness as the crystal and by means of spacers made of material with a suitable temperature coefficient, preferably with the coefficient zero, and the thickness of the desired air layer are held at a distance. 2. Socket according to claim 1, characterized in that the electrodes through Springs are pressed against the spacers. 3. Socket according to claim 1 and 2, characterized in that the intermediate pieces are arranged so that they can be easily replaced with selectable temperature constants. 1 sheet of drawings