RU175586U1 - PIEZOELEMENT - Google Patents

Abstract

Usage: for use in electronics. The essence of the utility model lies in the fact that the piezoelectric element is made of a quartz crystal cut yzb / (+ 35 ° 15 '... + 35 ° 17') in the form of a rectangular plate, the longitudinal axis of symmetry of which is located along the crystallographic axis Z ', with each at least one electrode having one contact area in the corner part of the surface is located on the surface of the plate, while the electrode on one of the surface of the plate has two contact areas located diagonally relative to each other, and in the remaining corner parts on both surfaces additionally located contact pads, with each contact pad located in each corner part of one surface is electrically connected to the contact pad located below it on the opposite surface. The width of the plate is in the range of values: 15 × H≤W≤16 × H, where W is the width of the piezoelectric plate, mm; N is the thickness of the piezoelectric plate, mm Effect: providing the ability to highlight the upper or lower side bands of the spectrum of the modulated signal. 4 s.p. f-ly, 2 ill.

Description

The utility model relates to radio electronics, in particular to piezotechnics, and can be used in the development and manufacture of frequency stabilization elements and signal selection.

Known piezoelectric elements of monolithic filters and resonators containing a rectangular piezoelectric plate with one or more pairs of overlapping exciting electrodes placed on its working faces with leads, the longitudinal axis of symmetry of which is aligned with the crystallographic axis Z 'or X. Known piezoelectric elements of monolithic filters and resonators work on the principle trapping energy in the sub-electrode region. The distance from the end face of the piezoelectric plate to the edge of the electrode coating is determined by the permissible level of loss of vibrational energy at the end face of the piezoelectric plate and, therefore, by sufficiently large dimensions both in width and in length of the piezoelectric element.

A known piezoelectric element containing a rectangular piezoelectric plate of an AT-cut, the longitudinal axis of symmetry of which is aligned with the crystallographic axis X of the quartz crystal, on the main faces of which are exciting electrodes with leads, while on the side of the ends of the piezoelectric plate on each of the opposite main faces symmetrically relative to the axis Z ', rectangular recesses are made, the ratio of the depth of each of which with the thickness of the piezoelectric plate is chosen equal to 0.5 (patent SU 1683477 A3, filing date and 11/14/1989, published on 01/30/1994).

A disadvantage of the known piezoelectric element is its poor quality factor and low processability, due to the photolithographic method of applying electrodes to the piezoelectric plate.

Known quartz piezoelectric element containing a crystalline element in the form of a round plate, on the front and rear surfaces of which are applied the first and second film exciting electrodes, respectively. The first film exciting electrode contains a first central part deposited on the front surface of the crystalline element in the zone of intersection of its optical and electrical axes, a first peripheral part deposited on the front surface of the crystalline element in the area adjacent to its end surface, and electrically connected to the first central part , and the second peripheral part deposited on the rear surface of the crystalline element in the area adjacent to its end surface, and electrically with union of the first peripheral portion. The second film exciting electrode contains a second central part deposited on the rear surface of the crystalline element in the zone of intersection of its optical and electrical axes, a third peripheral part deposited on the rear surface of the crystalline element in the area adjacent to its end surface, and electrically connected to the second central part the fourth peripheral part deposited on the front surface of the crystalline element in the area adjacent to its end surface, and electrically with union of the third peripheral portion (RU Patent No. 2,582,476 C1, the filing date of 03.02.2015, published on 27.04.2016, the).

The disadvantages of the known piezoelectric element include the fact that with an increase in the nominal frequency, the quartz plate becomes thinner, which will not allow it to be used in equipment used under high mechanical loads or vibration. The disadvantage is the round shape of the plate, which is not universal and does not provide interchangeability of elements in case of failure. In addition, the round shape of the plate complicates the manufacturing technology of piezoelectric elements. It is also not possible to use round plates with an increase in the order of such devices as piezoelectric filters in rectangular metal-glass cases, since it does not allow installing more than one piezoelectric element in these devices.

As the closest analogue, a piezoelectric element made of a quartz crystal cut yzb / 35 ° ll '± 5' in the form of a rectangular plate with two signal electrodes located on one surface of the plate and two low-potential (ground) electrodes on the opposite surface of the plate, each the electrode has one contact pad (terminal) in one of the corner parts of the plate, the longitudinal axis of symmetry of the plate is aligned with the crystallographic axis Z ', and the width of the plate is selected in a certain ratio :

14.70N≅W≅15.00N;

18.75H≅W≅19.05H;

25.65H≅W≅25.95H;

28.00 H≅W≅28.30 H;

38.55H≅W≅38.85H;

42.05N≅W≅42.35N, where W is the width of the piezoelectric plate, m; N is the thickness of the piezoelectric plate, m (patent RU 2032252 C1, filing date 08/10/1992, published 03/27/1995).

The disadvantage of the closest analogue is the inability to highlight the upper or lower sideband of the spectrum of the modulated signal.

The technical result obtained by using the claimed utility model consists in highlighting the upper or lower sideband of the spectrum of the modulated signal while decreasing the dynamic resistance, increasing the quality factor of the frequency resonators and the selectivity of the filters based on the claimed piezoelectric element.

The technical result is achieved by the fact that a piezoelectric element made of a quartz crystal in the form of a rectangular plate, the longitudinal axis of symmetry of which is located along the crystallographic axis Z ', while on each surface of the plate is located at least one electrode having one contact pad in the corner part of the surface, while the width of the plate is in the range of values: 15 × N≤W≤16 × N, where W is the width of the piezoelectric plate, mm; N is the thickness of the piezoelectric plate, mm, according to a useful model, the electrode on one of the plate surfaces is additionally equipped with a contact pad located diagonally relative to the other contact pad of the electrode, and contact pads are additionally located in the remaining corner parts of both surfaces, with each contact pad located in each corner part of one surface, it is electrically connected to the contact pad located under it on the opposite surface, and the crystal Vartsi slice has yzb / (+ 35 ° 15 '+ 35 ° ... 17').

Moreover, according to a utility model, an electrode having two contact pads can be intended for grounding.

Moreover, according to the utility model, at least one electrode located on the opposite surface from the electrode with two contact pads can be designed to excite the signal.

Moreover, according to a utility model, an electrode with two contact pads can have two peripheral parts and a middle part located between the peripheral parts.

Moreover, according to the utility model, the middle part of the electrode with two contact pads can be made narrower than the peripheral parts.

The present utility model is illustrated by the drawings shown in FIG. 1 and 2, an example of the implementation of a piezoelectric element, on which, however, is not the only possible, but clearly demonstrate the possibility of achieving the claimed technical result. At the same time, the given example of the implementation of the piezoelectric element does not limit the possibilities for implementing the utility model, which do not go beyond the framework of the utility model formula, and is not exhaustive.

In FIG. 1 shows the construction of a piezoelectric element in the form of a second-order unit for a piezoelectric filter of one side strip. In FIG. 2 shows a piezoelectric element with sprayed electrodes.

According to a utility model, the piezoelectric element is made of a quartz crystal with a slice yzb / (+ 35 ° 15 '... + 35 ° 17') (in other words, yzb / + 35 ° 16 '± 1') in the form of a rectangular plate 1, the longitudinal axis of symmetry of which is located along the crystallographic axis Z '(Fig. 1).

An electrode 2 and an electrode 3 are located on one of the surfaces of the plate 1, which can be designed to excite a signal (signal electrodes). The electrode 2 is the input, the electrode 3 is the output. The signal electrodes 2 and 3 are made with contact pads located in the corresponding angular parts of the surface of the plate 1, the signal electrode 2 has a contact pad (terminal) 5, and the signal electrode 3 has a contact pad 7. On the same surface of the plate 1 in the remaining (free , unoccupied, empty) corner parts are additionally located contact pads 6 and 8, which are electrically connected (for example, by metallization at the end of the plate) with contact pads 9 and 12 on the opposite surface of the plate 1 (f 1 g). The pads 9 and 12 are part of the electrode 4 and are located diagonally relative to each other.

The electrode 4 can be designed for grounding (grounding, low potential electrode). In this case, the grounding electrode 4 may contain two peripheral parts a and b and one middle part c located between the peripheral parts a and b (Fig. 1). In the free angular parts of this surface of the plate 1 are additional contact pads 10 and 11 (Fig. 1, 2), electrically connected to the corresponding pads 5 and 7 of the opposite surface of the plate 1.

The width of the plate is in the range of values:

15 × N≤W≤16 × N,

where W is the width of the piezoelectric plate, mm;

N is the thickness of the piezoelectric plate, mm

For example, for a piezoelectric element with a nominal frequency of 5 MHz, the thickness is 0.3332 mm, respectively, the width of the piezoelectric element is selected from the range of 4.998≤W≤5.3312 mm.

The piezoelectric element works as follows.

When applying to the contact pads 5 and 10 of the electrode 2 and the contact pads 9 and 6 of the peripheral part b of the electrode 4 of a high-frequency voltage with a frequency corresponding to the main vibrational shift of the thickness (or harmonic vibration), a shear standing wave is established in the sub-electrode region. Due to the acoustic coupling between the frequency input and output resonators, formed respectively by the electrode 2 and the peripheral part b of the electrode 4, as well as the electrode 3 and the peripheral part a of the electrode 4, the shear vibrations of the input resonator are transmitted to the sub-electrode region of the output resonator from the contact pads 7 , 8, 11 and 12 of which the high-frequency output signal is taken.

When creating the claimed piezoelectric element, its parameters were determined such as the shape of the quartz plate and its width, the orientation of its axis of symmetry, the angle of cut of the quartz crystal, the number of electrodes, the number of contact pads and their location, which together affect the achievement of certain technological characteristics. In this useful model, the characteristics are as follows: the ability to highlight the upper or lower sideband of the spectrum of the modulated signal, the ability to reduce dynamic resistance, increase the quality factor and selectivity of filters based on piezoelectric elements.

The set of essential features of the claimed utility model ensures the operation of frequency resonators without capturing the energy of unwanted resonators in the direction of its width. In this case, the absence of suction of vibrational energy by nearby unwanted modes of vibration provides not only a high mono-frequency of the piezoelectric element, but also leads to an increase in the quality factor of the frequency resonators, thereby reducing the squareness coefficient of the amplitude-frequency characteristics of the filters. The implementation of the piezoelectric element in accordance with the utility model allows to obtain the necessary bandwidth, which, in turn, after switching several piezoelectric elements in the filter circuitry, allows you to select the upper or lower side band of the spectrum of the modulated signal.

It is also possible to increase the size of the electrodes in width, which reduces the value of the dynamic resistance and increases the static capacitance of the resonators. The latter reduces the magnitude of the parasitic capacitance of the installation, and a decrease in dynamic resistance increases the quality factor of the frequency resonators and the selectivity of the filter.

Claims (5)

1. A piezoelectric element made of a quartz crystal in the form of a rectangular plate, the longitudinal axis of symmetry of which is located along the crystallographic axis Z ', while on each surface of the plate is located at least one electrode having one contact area in the corner of the surface, this plate width is in the range of values: 15 × N≤W≤16 × N, where W is the width of the piezoelectric plate, mm; H is the thickness of the piezoelectric plate, mm, characterized in that the electrode on one of the surfaces of the plate is additionally provided with a contact pad located diagonally relative to the other contact pad of the electrode, and contact pads are additionally located in the remaining corner parts of both surfaces, with each contact pad, located in each corner part of one surface, is electrically connected to the contact pad located under it on the opposite surface, and the crystal tsa has a slice yzb / (+ 35 ° 15 '... + 35 ° 17'). 2. The piezoelectric element according to claim 1, characterized in that the electrode having two contact pads is intended for grounding. 3. The piezoelectric element according to claim 1, characterized in that at least one electrode located on the opposite surface from the electrode with two contact pads is designed to excite a signal. 4. The piezoelectric element according to claim 1, characterized in that the electrode with two contact pads has two peripheral parts and a middle part located between the peripheral parts. 5. The piezoelectric element according to claim 4, characterized in that the middle part of the electrode with two contact pads is made narrower than the peripheral parts.

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