Biaxial High Temperature Strain Gauge

Biaxial high temp strain gauges are specifically designed for high-temperature and complex load testing scenarios. Combining a highly stable adhesive-based structure with precision strain grid technology, this industrial strain gauge deliver high-accuracy output and long-term reliability, making them suitable for both scientific research and industrial-grade strain analysis.

Specification

Features

1. Solderless Design: The strain gauge's integrated leads and test cables connect via crimping, eliminating any soldering and significantly improving wiring efficiency.
2. Extreme Temperature Range: Designed as a high temperature strain gauge, it operates from -200℃ to +250℃, ensuring stable performance in cryogenic and elevated-temperature structural testing.
3. 0-90° Biaxial Axis Design: This biaxial strain gauge enables dual-direction strain measurement with one installation, improving accuracy and efficiency in stress analysis and structural health monitoring.
4. Wide Measurement Range: As a precision resistive strain gauge, it offers a measurement range up to 20,000 με, making it suitable for both elastic and plastic deformation testing.

Tips: What's the difference between high temperature strain gauge and ordinary strain gauge?

High-temperature strain gauges and standard strain gauges appear similar in form, but from the sensitive grid material, substrate, adhesive, and leads to stability, they are all redesigned for high-temperature resistance. Standard strain gauges typically employ constantan alloy and polyimide adhesive substrates, with a typical temperature range of -30°C to +80°C. At higher temperatures, substrate softening, resistance drift, and adhesive failure occur, leading to measurement inaccuracies or even damage. High-temperature strain gauges, however, employ high-temperature alloys like Kama, platinum-tungsten, or Invar for the sensing grid. They incorporate heat-resistant adhesive bases, inorganic substrates, or ceramic substrates, paired with specialized high-temperature bonding adhesives and conductors. enabling operation at 200°C, 400°C, or even higher temperatures. They exhibit lower thermal output, reduced creep, and superior thermal stability, ensuring reliable measurements in harsh environments like engines, metallurgy, and high-temperature pipelines without accuracy degradation or structural failure due to heat.