DE1065473B - - Google Patents

Description

GERMAN

KL.21a4 10

INTERNAT. KL. H 03 h

PATENT OFFICE

G 23373 VIIIa / 2la ⁴

REGISTRATION DATE: NOVEMBER 15, 1957

NOTICE
LOGIN
AND ISSUE OF THE
EDITORIAL: SEPTEMBER 17, 1959

The invention relates to a piezoelectric element, which in particular consists of a crystal made of quartz, Tourmaline or Seignette salt or a block of ferroelectric material, such as. B. barium titanate, is made, with an electrode on at least one of its surfaces by an electrical conductive surface covering is formed.

It is known that certain crystals, e.g. B. quartz, tourmaline and Seignette salt, the piezoelectric Effects show how control or regulating elements can be used to adjust the frequency e.g. B. to keep an electrical oscillator circuit stable. The frequency at which such crystals vibrate changes slightly with temperature, and in many applications, for example when the Crystal regulates the frequency of a main oscillator in a carrier telephone system, it is essential that Keep the oscillation frequency constant despite the temperature change. It is known the crystal control element for this purpose to be arranged in an oven, which is provided with thermostatic temperature control is. However, such an arrangement necessarily involves a large amount of space, and a relatively large amount of electrical energy is consumed to heat the furnace and operate the required thermostatic control.

The object of the invention is to create crystal elements for use in electrical oscillator circuits, where the oven arrangement described above for temperature control is not required will.

This is achieved according to the invention in that the electrode has a connection at each end provided and so switched, arranged and dimensioned in their strength so that they are the resistance element forms an electrical heating circuit, by means of which the element can be heated to its Maintain temperature at a desired value. This element can be made from a crystal, from quartz, Tourmaline or Seignette salt or from a body made of ferroelectric ceramic material, such as Barium titanate.

Two such electrically conductive surface coverings can also be on the two opposite surfaces this element be provided. The electrically conductive surface coverings can also be used as Electrodes are used to which the oscillation potential of an electrical oscillator circuit is created.

The heating circuit that includes the electrically conductive surface covering or the electrically conductive surface covering, is expediently regulated in the usual way as a function of the temperature.

Piezoelectric element
and its method of manufacture

as well as circuit
with such an element

Applicant:

The General Electric Company Limited,
London

Representative:

Dr.-Ing. H. Ruschke, Berlin-Friedenau, Lauterstr. 37,

and Dipl.-Ing. K. Grentzenberg, Munich 27,

Patent attorneys

Claimed priority:
Great Britain 16 November 1956

Arthur Edward Harrold,

Coventry, Warwickshire (UK),

has been named as the inventor

Such an electrically conductive surface covering is preferably produced in the same way like the well-known printed circuits. A conductive one to be produced on a surface of an element Surface covering can be formed, for example, that those parts of a substantially continuous layer of conductive material by acid etching, electro-etching or electrical Spark erosion, which is not required. The surface of the element must be covered accordingly before applying the conductive layer. The electrically conductive surface covering may be formed from silver or gold and have a thickness on the order of approximated Have 0.5 μ. ■■: · ■ '·. ■

The heating current applied to the electrically conductive Surface coverings supplied can be direct current.

A piezoelectric crystal element designed according to the invention and an electrical oscillator circuit, whose frequency is stabilized by such a crystal element, are now on hand

909 628/279

■ :: 3 ^ίΤ . : '.: ■. ·. 3 4

of a temperature sensor arrangement shown in the drawing described. It shows ■ the delivery of direct current to the criminal

Fig. 1 is a perspective view of the crystal stall resistance element being controlled.

element ,. . The first branch of the oscillator bridge 16

^ Fig. 2, a schematic cross-section through a 5 contains the crystal element 1 and an in-line arrangement, the "'contains" such a crystal element, switched balancing capacitor 17, the second bridge' Fig; 3 the circuit of an electrical oscillator, branch a resistor 18, the third branch a containing such a crystal element. Tungsten filament lamp 19 (but this can also '•' ^ Iti'Fig. 1 includes "das'Kristallelement 1, which by a thermistor or a nonlinear Frequency of the resistor of another type to be described with reference to FIG. 3) and the electrical oscillator stabilized, a flat fourth branch a resistor 20. The node cut, which is cut from a quartz crystal, 21 of the first and fourth bridge branches are grounded, where 'the'Kristallelement 1 two larger planar upper The vibrations in the bridge 16 are through has areas 2 and 3. The surface 2 of the crystal is maintained by an amplifier 22, the two one-element 1 is provided with a conductive coating 4 with specific 15 input terminals 23 and 24 as well as two output terminals Provided shaping, which has 25 and 26 as crimps in the following. The input terminal 23 is on Stall resistance element is designated. Opposite node 27 of the third and fourth branches Overlying surface 3 ^ has a normal electrode bridge 16 and the input terminal 24 is on the trode 5. The crystal resistance element 4 becomes the junction point 28 of the first and second branches of FIG produced in that the 'surface 2 of the Kria bridge 16 is connected. The output terminals 25 stalls 1 in. suitable. Way partially covered and and 26 of the amplifier 22 are connected to the node then silver sprayed 29 of the second and third branches of the bridge 16 thereon in a vacuum or is vaporized. The process is continued or connected to earth.

continues until the deposited on the surface 2 in the first branch of the bridge 16 is the crystal silver has a thickness of about 0.5 μ. The shape of the 25 element 1 arranged so that the line 30 between crystal resistance element 4 is such that it is the normal electrode 5 and the adjustment capacitor. ' -Resistance path between an input sator 17, while the line 31 connects the crystal point '6 and an' output point '7 ^ resistance element 4 with the node 21 of the width of the gap 8 between adjacent parts of the first and fourth branches of the bridge 16, the crystal resistance element the order of magnitude 30 has the other lead 32 to the crystal of 0.4 mm. . ::. ^J ; ment 4 is connected to a further bridge circuit 33

; The _: on that. Entry point 6 and the. Exit closures, which will be described below, and

point; 7. soldered connection lines 9 or 10 and also shunted to earth via a suitable

the termination line 11 (FIG. 2), the capacitance 34 connected to the points 12.

of the electrode 5 on the surface 3 of the crystal 35 The further bridge circuit 33 comprises one element 1 are soldered, are appropriately designed ■ first, second and third resistor 35, 36 or forms that they the crystal element 1 within a 37, which in the first, second and third branch of the Glass or metal envelope 13 are able to carry. Bridge 33 are connected, the crystal resisting mica discs 14 can be provided to stand element 4 in the fourth branch of the bridge 33 any excessive movement of the crystal 4 ° is arranged. The resistors 35, 36 and 37 have element 1 limit, creating a break of the same resistance value, which is the same lines 9, 10 and 11 could be caused. In size like the resistance of the crystal resistance normal In operation, the crystal element 1 has the GHm element 4. The DC power supply of the Krimer discs 14 do not touch. The purpose of the stall resistance element 4 is by an equal. Enclosure 13 consists of. Heat losses from the 45 current amplifier 38 are maintained. The input crystal element 1 to decrease. A stronger clamp 39 and 40 of the amplifier 38 are connected to the thermal insulation can in "; in a known manner, junction 43 of the first and second branches of the can still be caused by the fact that the sheath 13 bridge 33 or the node 44 of the third and evacuated and provided with double walls, connected to the fourth branch of the bridge 33, and at the space 15 between the walls evacuated 50 the output terminals 41 and 42 are with the knowird, or in that the envelope 13 made of glass tenpunkt 45 of the second and third branches of the exists and some or all of the surfaces of the wall bridge 33 or connected to earth. The knot endings the envelope 13 are silver-plated. point 46 of the first and fourth branches of the bridge

The oscillator circuit shown in Fig. 3 has 33 is also grounded.

a crystal-controlled bridge, with a further 55 The arrangement is made in such a way that a

Bridge circuit for the ¹ supply and regulation of increased voltage to the crystal resistance element 4

■ the direct current for heating the crystal element 1 is applied when the temperature of the crystal

;is provided. ■ '· ". Element 1 falls, and vice versa, so that the temperature

■ The crystal resistance element 4 has at this temperature of the crystal element 1 and therefore the vibration

Circuit to fulfill three functions ^1. First, 60 forms the frequency of the bridge 16 is kept constant.

ϊes one of the electrodes of the crystal element 1, from Fig. 1 it can be seen that the crystal resistance

the "on the opposite surface 4 of the crystal element 4 in the manner of printed circuits

Stable element 1 formed electrode 5 the other can be applied by, for example, a

Electrode'. is. Second, 'forms the crystal-resisting silver layer on the partially covered

- Stand element 4, the wide'r'stand element of a heating surface 2 of the crystal element 1 is sprayed

arrangement by means of which the crystal element 1 or the undesired parts of a continuous

■ Heat is supplied to it on the required metal layer on the surface 2 by acid etching

■ Maintain temperature and thus remove the required or electrical spark erosion. In

• Maintain vibration frequency. Thirdly, the unwanted parts can be used in a different way

. 'the crystal resistance element4 forms the resistance of a continuous metal layer on the upper

surface 2 can be removed by electroetching, the surface being used as the anode in an electrolytic Cell acts and the unwanted parts of the surface that are not covered by electrolytic Effect can be removed. The invention is not limited to the case where the crystal resistance element 4 is formed from silver, since other metals, such as gold, are also used can.

Although the described embodiment of the invention is an oscillator circuit, it is noted that that the invention applies equally to other circuits, such as an electrical filter network, is applicable, in which the frequency is stabilized by a piezoelectric element, whose change in resonance frequency due to a change in temperature exceeds the permissible level if no temperature control takes place.

The invention can be applied to any piezoelectric element in which electrodes are applied to the surface of a body made of piezoelectric material. Besides quartz can for example tourmaline, Seignette salt or a sintered block of ferroelectric ceramic Material such as barium titanate can be used.

Claims (7)

Patent claims: 1. Piezoelectric element, which in particular consists of a crystal made of quartz, tourmaline or Seignette salt or a block of ferroelectric material such as barium titanate is, wherein on at least one of its surfaces an electrode through an electrically conductive Surface covering is formed, characterized in that the electrode has a connection provided at each end and arranged so connected and dimensioned in their strength so that it forms the resistance element of an electrical heating circuit, by means of which the element is heated can be to keep its temperature at a desired value. 2. Piezoelectric element according to claim 1, characterized in that the conductive surface covering is made of silver or gold and has a thickness of approximately 0.5μ. 3. Piezoelectric element according to claim 1 or 2, characterized in that it is in itself known way within a glass, preferably evacuated envelope is arranged, which optionally has double walls, the space between the walls is evacuated. ^ 4. A method for manufacturing a piezoelectric element according to any one of the preceding Claims, characterized in that the electrically conductive surface coverings are known per se Way to be made in the manner of printed circuits. 5. The method according to claim 4, characterized in that the electrically conductive surface coverings are generated in that those parts of the surface of the element im essential continuous layer of conductive material by acid etching, electro-etching or electrical spark erosion, which is not required. .6. Method according to Claim 4, characterized in that the electrically conductive surface coverings can be produced in that a conductive layer is applied by spraying or vapor deposition the surface of the element is applied after it is partially covered accordingly has been. 7. Electrical oscillator circuit using a piezoelectric element according to one of claims 1 to 3, characterized in that at least one of the electrically conductive Surface coverings not only as a heating element, but also as a resistance element in a temperature sensor arrangement is used. Considered publications:
German Patent No. 552 771;
U.S. Patent Nos. 1,791,804, 2,004,170. 1 sheet of drawings © 909 628/279 9 ·.