Omega TQ103 Owner Manual

Below you will find brief information for socket extension torque sensor TQ103 TQ103-25, socket extension torque sensor TQ103 TQ103-50, socket extension torque sensor TQ103 TQ103-125, socket extension torque sensor TQ103 TQ103-200, socket extension torque sensor TQ103 TQ103-600. The OMEGA® TQ103 Series socket extension torque sensor is ideal for installation between a socket and drive to measure or verify bolt torque. The sensor can measure torque in both clockwise and counterclockwise directions. Any electronic display or control device which is compatible with strain gage transducers may be used with the sensor. The sensors are available in 1/4", 3/8", 1/2", and 3/4" square drives.

PDF Download
Document
OMEGA TQ103 Socket Extension Torque Sensor Instruction Sheet | Manualzz

Advertisement

Advertisement

Advertisement

Key features

  • clockwise and counterclockwise torque measurement
  • compatible with strain gage transducers
  • variety of square drive sizes (1/4", 3/8", 1/2", 3/4")
  • high accuracy: 0.37% F.S.
  • wide operating temperature range: -65°F to +250°F
  • stable hysteresis loop
  • second degree calibration curve

Frequently asked questions

The OMEGA TQ103 series socket extension torque sensor is designed to measure or verify bolt torque in both clockwise and counterclockwise directions, making it suitable for a variety of torque-related applications.

The sensor boasts a high accuracy of 0.37% of full scale, ensuring reliable torque measurement within its designated range.

The OMEGA TQ103 series socket extension torque sensor can operate within a temperature range of -65°F to +250°F, making it suitable for various environments.

The OMEGA TQ103 series socket extension torque sensor is available in four square drive sizes: 1/4", 3/8", 1/2", and 3/4", offering compatibility with a wide range of tools and fasteners.

The calibration curve for the sensor is generated through a process involving cycling it through the operating range to develop a stable hysteresis loop. Known loads are then applied to the sensor with a reference load cell, and the data is best fitted to second-degree equations to generate theoretical sensor outputs at various load points. These equations are then used to create the calibration sheet which describes the ascending, descending, and average calibration curves.
ALP:
Preparing document for printing…
0%