Shock Sensors

Part Number	Description / PDF	Quantity
W2DL-02 Omron Electronics Components	SENSOR SHOCK BALL 5-12V	22
75MCD/15G SpotSee	75 MINICLIP: DOUBLE TUBE*	300
33285 SpotSee	FLEX 85: DOUBLE TUBE*	200
33275 SpotSee	FLEX 75: DOUBLE TUBE*	200
33075 SpotSee	FLEX 75: SINGLE TUBE*	200
75MC/15G SpotSee	75 MINICLIP: SINGLE TUBE*	300
32300 SpotSee	47 CLIP: SINGLE TUBE - CX47	200
65MC/25G SpotSee	65 MINICLIP: SINGLE TUBE	300
32220 SpotSee	75 CLIP: DOUBLE TUBE - CXX75*	300
32100 SpotSee	30 CLIP: SINGLE TUBE - CX30	300
PKGS-00GXP1-R TOKO / Murata	SHOCK SENSOR	0
32330 SpotSee	85 CLIP: DOUBLE TUBE - CXX85*	300
55MCD/37G SpotSee	55 MINICLIP: DOUBLE TUBE	300
22423 SpotSee	47 SHOCKWATCH TUBE - 50G	1000
47MCD/50G SpotSee	47 MINICLIP: DOUBLE TUBE	250
33247 SpotSee	FLEX 47: DOUBLE TUBE	200
32400 SpotSee	65 CLIP: SINGLE TUBE - CX65	275
32905 SpotSee	55 CLIP: DOUBLE TUBE - CXX55	300
30MC/100G SpotSee	30 MINICLIP: SINGLE TUBE	300
33035 SpotSee	FLEX 35: SINGLE TUBE	200

Shock Sensors

1. Overview

Shock sensors are transducers designed to detect and measure sudden acceleration or deceleration forces caused by impacts, vibrations, or mechanical shocks. These devices convert mechanical energy into electrical signals for analysis, enabling system protection, data logging, or triggering control actions. As critical components in condition monitoring and safety systems, shock sensors play vital roles in automotive, aerospace, industrial automation, and consumer electronics sectors.

2. Main Types & Functional Classification

Type	Functional Characteristics	Application Examples
Mechanical Switch Sensors	Simple on/off contact activation at threshold acceleration	Package tamper detection, vehicle airbag deployment
MEMS Capacitive Sensors	Micromachined structures with capacitive detection, digital output	Smartphone orientation, HDD protection, industrial IoT
Strain Gauge Sensors	Resistive elements measuring mechanical deformation	Structural health monitoring, vehicle crash testing
Piezoelectric Sensors	Crystal elements generating voltage under mechanical stress	High-frequency vibration analysis, weapon system monitoring
Magnetic Sensors	Electromagnetic induction for shock detection	Railway vibration monitoring, seismic activity detection

3. Structure & Components

Typical shock sensor construction includes: 1) Sensing element (MEMS structure, piezoelectric crystal, or strain gauge), 2) Signal conditioning circuitry (amplifiers, filters), 3) Housing (metallic or polymer enclosure for environmental protection), 4) Electrical interface (wired connectors or wireless transceivers). High-performance variants incorporate hermetic sealing for extreme environments and integrated microcontrollers for signal processing.

4. Key Technical Specifications

Parameter	Description	Importance
Measurement Range	Maximum/minimum detectable acceleration ( 2g to 5000g)	Determines sensor suitability for specific shock severity
Frequency Response	Operating bandwidth (0.5Hz-10kHz typical)	Affects transient event capture accuracy
Resolution	Minimum detectable change (0.01g-0.1g)	Impacts measurement precision
Shock Survival Rating	Maximum non-destructive input level	Ensures device durability in extreme conditions
Operating Temperature	Functional range (-55 C to +125 C)	Environmental reliability indicator
Output Type	Analog voltage/digital (I2C, SPI, CAN)	System integration compatibility

5. Application Fields

Primary industries include: Automotive (airbag triggering, crash diagnostics), Industrial (machinery condition monitoring, pipeline integrity), Consumer Electronics (mobile device drop detection), Aerospace (flight recorder activation), Security (asset tracking, tamper alarms), Medical (implantable device monitoring). Typical equipment: Automotive crash test dummies, structural health monitoring systems, package tracking devices.

6. Leading Manufacturers & Products

Manufacturer	Product Series	Key Features
Analog Devices	ADXL375	3-axis MEMS, 2000Hz bandwidth, automotive qualified
TE Connectivity	EPIC Series	Hermetic sealing, 5000g range, MIL-STD-810G
PCB Piezotronics	356A15	Piezoelectric, 10kHz response, -55 C to +160 C
STMicroelectronics	LSM6DSOX	MEMS with AI edge processing, 6.5kHz ODR
Kistler Group	8692C	High-precision charge output, 0.1-10000Hz

7. Selection Recommendations

Key considerations: 1) Required measurement range vs. expected shock levels, 2) Environmental conditions (temperature, humidity), 3) Frequency response matching application dynamics, 4) Output compatibility with existing systems, 5) Mounting constraints (PCB footprint, weight), 6) Calibration traceability (ISO 17025 requirements), 7) Cost vs. performance trade-offs. For example, MEMS sensors suit low-g consumer applications while piezoelectric types handle high-frequency industrial shocks.

8. Industry Trends

Current developments focus on: Miniaturization via advanced MEMS fabrication, Wireless sensor integration with BLE/LoRa protocols, Edge AI processing for anomaly detection, Improved temperature stability through material innovation, Multi-axis sensing in compact packages, Enhanced durability for harsh environments (IP68+, radiation resistance). Market growth driven by automotive safety regulations (ISO 26262) and predictive maintenance adoption across industries.