Calibration Experiment and Temperature Compensation Method for the Thermal Output of Electrical Resistance Strain Gauges in Health Monitoring of Structures
<p>Wheatstone bridge circuit.</p> "> Figure 2
<p>The “zero drift” data for a strain gauge.</p> "> Figure 3
<p>Strain gauges pasted on measured materials with different linear expansion coefficients: (<b>a</b>) epoxy resin adhesive, (<b>b</b>) aluminum, (<b>c</b>) brass, (<b>d</b>) stainless steel, (<b>e</b>) iron, (<b>f</b>) concrete, (<b>g</b>) plexiglass, and (<b>h</b>) granite.</p> "> Figure 4
<p>Thermostats with dual temperatures. (<b>a</b>) high- and low-temperature thermostats: −40∼150 °C (±0.1 °C); (<b>b</b>) Ambient temperature thermostats: 15∼50 °C (±0.1 °C).</p> "> Figure 5
<p>Thermal output of the strain gauges pasted onto different materials: (<b>a</b>) epoxy resin adhesive; (<b>b</b>) free strain gauge, aluminum, brass, stainless steel, iron; (<b>c</b>) concrete, plexiglass, granite.</p> "> Figure 6
<p>Fitting line of the thermal output of strain gauges pasted onto different measured materials: (<b>a</b>) epoxy resin adhesive; (<b>b</b>) free strain gauge, aluminum, brass, stainless steel, iron; (<b>c</b>) concrete, plexiglass, granite.</p> "> Figure 7
<p>Coupled deformation of strain gauges and measured materials during temperature change: (<b>a</b>) α<sub>s</sub> < α<sub>g</sub>; (<b>b</b>) α<sub>s</sub> > α<sub>g</sub>.</p> "> Figure 8
<p>Strain gauges pasted on adhesive layers with different thicknesses: (<b>a</b>) 0; (<b>b</b>) 0.5 mm; (<b>c</b>) 1.0 mm; (<b>d</b>) 2.0 mm; (<b>e</b>) 3.0 mm; (<b>f</b>) 4.0 mm; (<b>g</b>) 5.0 mm.</p> "> Figure 9
<p>Relationship of temperature to thermal output for different paste thicknesses of the adhesive layer.</p> ">
Abstract
:1. Introduction
2. Principle of Thermal Output of Electrical Resistance Strain Gauges
2.1. Measurement Principle of Electrical Resistance Strain Gauges
2.2. Coupled Thermo-Electro-Elasticity Equations
2.3. Elastic Constitutive Relation
3. Temperature Calibration Experiments for Different Measured Materials
3.1. Zero-Drift Experiment
3.2. Calibration Experiments for the Thermal Output of Different Measured Materials
3.3. Calculation of the Thermal Output for Different Measured Materials
3.4. Coupled Deformation Analysis of Strain Gauges and Measured Materials
3.5. Analysis of the Error Caused by the Thickness of an Adhesive Layer
4. Conversion Relationship of Strain Gauge Thermal Output for Different Materials
4.1. Calculation Principle
4.2. Calculation Example
5. Conclusions
- (1)
- The thermal output curves applicable to different materials were obtained based on temperature calibration tests conducted on a variety of materials. The thermal output shows a linear relationship with temperature, and the thermal output compensation value at each temperature can be calculated according to the thermal output fitting formula.
- (2)
- When the coefficient of linear expansion of the measured material is larger or much smaller than that of the strain gauge grating material, the two thermal output curves show an opposite trend. This means that when the coefficient of linear expansion of the measured material is larger than that of the strain gauge grating material, the elongation of the strain gauges is promoted, and thus, the thermal output during the temperature change is increased. When the coefficient of linear expansion of the measured material is smaller than that of the strain gauge grating material, the elongation of the strain gauges is prevented, and thus, the thermal output decreases.
- (3)
- The thickness of the adhesive layer between the strain gauge and the measured object affects the thermal output. The thermal output of the strain gauge increases significantly when the thickness of the adhesive layer is in the range of 0.5 to 2 mm. When the thickness of the adhesive layer reaches 2 mm, the increase in the thermal output of the strain gauge is no longer significant. This difference is relatively small within 20 °C but becomes increasingly larger as the temperature increases.
- (4)
- The thermal output conversion relationships were derived for materials with different linear expansion coefficients. The thermal output of material B was estimated from the thermal output of material A and the linear expansion coefficients of the two materials (A and B), and the maximum difference between the estimated and actual values was within 10% in the range of 10 °C to 50 °C.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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T/°C | Epoxy Resin Adhesive | Free Strain Gauge | Aluminum | Brass | Stainless Steel | Iron | Concrete | Plexiglass | Granite |
---|---|---|---|---|---|---|---|---|---|
10 | −34 | −12 | 25 | 15 | 10 | 14 | 2 | −7 | −7 |
20 | 1128 | 245 | 242 | 202 | 138 | 53 | −14 | −51 | −76 |
30 | 2359 | 497 | 435 | 337 | 227 | 71 | −38 | −95 | −156 |
40 | 4636 | 825 | 607 | 495 | 319 | 55 | −101 | −156 | −257 |
50 | 5711 | 1295 | 778 | 622 | 400 | 43 | −166 | −214 | −352 |
T/°C | ΔT/°C | ||||
---|---|---|---|---|---|
10 | 0 | / | / | / | / |
20 | 10 | 202 | 256 | 242 | 5.8% |
30 | 20 | 337 | 445 | 435 | 2.3% |
40 | 30 | 495 | 657 | 607 | 8.2% |
50 | 40 | 622 | 838 | 778 | 7.7% |
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Jin, Z.; Li, Y.; Fan, D.; Tu, C.; Wang, X.; Dang, S. Calibration Experiment and Temperature Compensation Method for the Thermal Output of Electrical Resistance Strain Gauges in Health Monitoring of Structures. Symmetry 2023, 15, 1066. https://doi.org/10.3390/sym15051066
Jin Z, Li Y, Fan D, Tu C, Wang X, Dang S. Calibration Experiment and Temperature Compensation Method for the Thermal Output of Electrical Resistance Strain Gauges in Health Monitoring of Structures. Symmetry. 2023; 15(5):1066. https://doi.org/10.3390/sym15051066
Chicago/Turabian StyleJin, Zhihao, Yuan Li, Dongjue Fan, Caitao Tu, Xuchen Wang, and Shiyong Dang. 2023. "Calibration Experiment and Temperature Compensation Method for the Thermal Output of Electrical Resistance Strain Gauges in Health Monitoring of Structures" Symmetry 15, no. 5: 1066. https://doi.org/10.3390/sym15051066
APA StyleJin, Z., Li, Y., Fan, D., Tu, C., Wang, X., & Dang, S. (2023). Calibration Experiment and Temperature Compensation Method for the Thermal Output of Electrical Resistance Strain Gauges in Health Monitoring of Structures. Symmetry, 15(5), 1066. https://doi.org/10.3390/sym15051066