Buzzer Elements, Piezo Benders

Part Number	Description / PDF	Quantity
7BB-20-3 TOKO / Murata	BUZZER ELEMENT STD 3.6KHZ 20MM	12890
7BB-15-6L0 TOKO / Murata	BUZZER ELEMENT STD 6KHZ 15MM	1990
7BB-35-3 TOKO / Murata	BUZZER ELEMENT STD 2.8KHZ 35MM	3338
7BB-20-6 TOKO / Murata	BUZZER ELEMENT STD 6.3KHZ 20MM	83
7BB-35-3C TOKO / Murata	BUZZER ELEMENT FDBK 2.8KHZ 35MM	206
7BB-27-4C TOKO / Murata	BUZZER ELEMENT FDBK 4.6KHZ 27MM	609
7BB-41-2L0 TOKO / Murata	BUZZER ELEMENT STD 2.2KHZ 41MM	375
7BB-35-3L0 TOKO / Murata	BUZZER ELEMENT STD 2.8KHZ 35MM	56
7BB-15-6 TOKO / Murata	BUZZER ELEMENT STD 6KHZ 15MM	0
7BB-41-2C TOKO / Murata	BUZZER ELEMENT FDBK 2.2KHZ 41MM	0
7BB-12-9 TOKO / Murata	BUZZER ELEMENT STD 9KHZ 12MM	4040
7BB-20-6L0 TOKO / Murata	BUZZER ELEMENT STD 6.3KHZ 20MM	7367
7BB-27-4 TOKO / Murata	BUZZER ELEMENT STD 4.6KHZ 27MM	959
7BB-27-4L0 TOKO / Murata	BUZZER ELEMENT STD 4.6KHZ 27MM	0
7NB-41-1 TOKO / Murata	BUZZER ELEMENT STD 800HZ 41MM	38
7BB-20-6C TOKO / Murata	BUZZER ELEMENT FDBK 6.3KHZ 20MM	0
7BB-20-6CL0 TOKO / Murata	PIEZO BUZZERS	0
7BB-41-2CL0 TOKO / Murata	PIEZO BUZZERS	0
7BB-27-4CL0 TOKO / Murata	PIEZO BUZZERS	558
7NB-31R2-1 TOKO / Murata	PIEZOELECTRIC DIAPHRAM	0

1. Overview

Buzzer elements and piezo benders are electroacoustic transducers based on the piezoelectric effect. Buzzer elements generate audible sound through mechanical vibration when subjected to an electric field, while piezo benders utilize flexible piezoceramic materials to convert electrical energy into mechanical displacement. These components play critical roles in modern electronics for audible alerts, precision actuation, and sensor applications.

2. Main Types and Functional Classification

Type	Function Features	Application Examples
Piezoelectric Buzzer Elements	High-frequency tone generation, compact size, low power consumption	Alarm systems, consumer electronics, medical devices
Single-layer Piezo Benders	Simple structure, low-voltage operation, moderate displacement	Valve control, microfluidic pumps, tactile feedback
Multi-layer Piezo Benders	Amplified displacement, high force output, complex motion control	Industrial automation, precision positioning, aerospace actuators
Surface-mount Piezo Devices	Miniaturized SMD packaging, automated assembly compatibility	Wearable devices, IoT sensors, automotive electronics

3. Structure and Composition

Typical construction includes:

Piezoceramic layer (PZT, PMN-PT materials)
Metal substrate (brass, stainless steel, or flexible PCB)
Electrode layers (silver, gold, or ITO coatings)
Protective encapsulation (epoxy resin or polymer coating)

Resonant cavity structures optimize acoustic performance in buzzers, while benders employ cantilever or unimorph designs for mechanical displacement.

4. Key Technical Specifications

Parameter	Description
Operating Voltage	3-15V DC for buzzers, 10-200V AC for high-displacement benders
Resonant Frequency	1-10 kHz range determines audible pitch and efficiency
Sound Pressure Level (SPL)	70-110 dB at 10cm distance for buzzers
Displacement Range	0.1-5mm depending on layer configuration
Temperature Stability	Operational range: -40 C to +85 C

5. Application Areas

Consumer Electronics: Smartwatches, smartphones, home appliances
Industrial Equipment: Machinery status alerts, valve actuators
Medical Devices: Infusion pumps, diagnostic equipment
Automotive Systems: Seatbelt reminders, fuel injector controls
Telecommunications: Network equipment alarms

6. Leading Manufacturers and Products

Manufacturer	Representative Product
Murata Manufacturing	PKMCS040A3H-Z
Panasonic Electronic Components	ENV-40DRW
TE Connectivity	1-1431485-1
CUI Devices	PB-4055-SMT

7. Selection Guidelines

Key considerations:

Required sound pressure level and frequency characteristics
Environmental conditions (temperature, humidity, vibration)
Power supply constraints and current limitations
Physical size and mounting method compatibility
Reliability requirements (MTBF > 100,000 hours typical)

For piezo benders, evaluate displacement-force trade-offs and actuation speed requirements.

8. Industry Trends

Emerging developments include:

Miniaturization for wearable device integration
Energy-efficient designs using novel piezoelectric materials
Integration with MEMS technology for smart actuators
Increased adoption in IoT sensors and haptic feedback systems
Development of lead-free piezoceramics for environmental compliance

Market growth projected at 6.2% CAGR through 2030 driven by automotive and medical electronics demand.