Piezo Electric Crystals:

Piezo Electric Crystals Principle, Construction, working, Advantages and Disadvantages

The crystals which produce piezo-electric eect and converse Piezo electric effect are termed as Piezo electric crystal. Example: Quartz, Tourmaline, Rochelle Salts etc.

Piezo Electric Crystals

The crystals which produce piezo-electric effect and converse Piezo electric effect are termed as Piezo electric crystal.

Example: Quartz, Tourmaline, Rochelle Salts etc.

At typical example or a piezo electric crystal (Quartz) is as shown

It has an hexagonal shape with pyramids attached at both ends. It consists of 3 axes. Viz.,

(i) Optic Z axis, which joins the edges of the pyramid

(ii) Electrical axis(X axis), which joins the corners of the hexagon and

(iii) Mechanical axis, which joins the center or sides of the hexagon as shown

X-cut and Y cut crystals

X-Cut crystal:

When the crystal is cut perpendicular to the X-axis, as shown in the figure 1.4.2, then it is called X-crystals.

Generally X-cut crystals are used to produce longitudinal ultrasonic waves.

Y-Cut Crystal:

When the crystal is cut perpendicular to the Y-axis, as shown in the figure 1.4.3, then it is called Y-cut crystal.

Generally, Y-Cut crystal produces transverse ultrasonic waves.

Piezoelectric Effect

Definition: When a mechanical stress is applied to the mechanical axis with respect to optical axis, a potential difference is developed across the electrical axis with respect to optic axis

Inverse Piezoelectric Effect:

Definition: When an alternating electric field is applied to electrical axis with respect to optical axis, expansion or contraction takes place in the mechanical axis with respect to optical axis.

Production of Ultra sonic waves – Piezo Electric Effect

Principle:

This is based on the Inverse piezoelectric effect.

When a quartz crystal is subjected to an alternating potential difference along the electric axis, the crystal is set into elastic vibrations along its mechanical axis.

If the frequency of electric oscillations coincides with the natural frequency of the crytal, the vibrations will be of large amplitude.

If the frequency of the electric field is in the ultrasonic frequency range, the crystal produces ultrasonic waves.

Construction:

The circuit diagram is shown in the figure 1.5

It is base turned oscillator circuit.

A slice of Quartz crystal is placed between the metal plates A and B so as to form a parallel plate capacitor with the crystal as the dielectric.

This is coupled to the electronic oscillator through the primary coil L₃ of the transformer.

Coils L₂ and L₁ of oscillator circuit are taken for the primary of the transformer. The collector coil L₂ is inductively coupled to base coil L₁.

The coil L₁ and variable capacitor C form the tank circuit of the oscillator.

Working:

When the battery is switched on, the oscillator produces high frequency oscillations.

An oscillatory e.m.f is induced in the coil L3 due to transformer action.

So the crystal is now under high frequency alternating voltage.

The capacitance of C1 is varied so that the frequency of oscillations produced is in resonance with the natural frequency of the crystal.

Now the crystal vibrates with larger amplitude due to resonance.

Thus high power ultrasonic waves are produced.

Condition for Resonance:

Frequency of the oscillator circuit = Frequency of the vibrating crystal

Where ‘l’ is the length o the rod

‘E’ is the Young’s modulus o the rod

‘ρ’ is the density of the material of the rod.

‘P’ = 1,2,3 …. Etc for fundamental, first overtone, second overtone etc respectively

Advantages:

Ultrasonic frequencies as high as 500MHz can be generated.
The output power is very high. It is not affected by temperature humidity.
It is more efficient than the Magnetostriction oscillator.
The breadth of the resonance curve is very small. So we can get a stable and constant frequency of ultrasonic waves.