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Thin Circular Ring Radius Temperature Change

Reference data and engineering information about thin circular ring radius temperature change for thermodynamics applications.

thincircularringradius

Overview

Engineering reference data for Thin Circular Ring Radius Temperature Change in thermodynamics.

Key Formulas

First Law

ΔU=QW\Delta U = Q - W

Energy is conserved — heat added minus work done.

Ideal Gas Law

PV=nRTPV = nRT

Relates pressure, volume, and temperature of an ideal gas.

Heat Transfer

Q=mcΔTQ = mc\Delta T

Sensible heat transfer.

Carnot Efficiency

η=1TC/TH\eta = 1 - T_C/T_H

Maximum efficiency between two temperatures.

Variables

SymbolDescriptionUnit
UUInternal energyJ
QQHeatJ
WWWorkJ
PPPressurePa
VVVolume
TTTemperatureK

Example: Steel Pipe Diameter Temperature Expansion

A stainless steel pipe with nominal diameter 10 inches (outside diameter 10.750 inches) is heated from 68°F to 98°F. The expansion coefficient for stainless steel S30100 is 9.4 μin/in°F.

Using the diameter expansion formula:

d1=d0(dtα+1)d_1 = d_0 (dt \cdot \alpha + 1)

Substituting the values:

d1=10.750in×((98°F68°F)×0.0000094inin°F+1)=10.753ind_1 = 10.750 \, \text{in} \times \left( (98\,°\text{F} - 68\,°\text{F}) \times 0.0000094 \, \frac{\text{in}}{\text{in}·°\text{F}} + 1 \right) = 10.753 \, \text{in}

Temperature Expansion Calculator

Calculate the final diameter of a thin circular ring after temperature expansion. This calculator works with both metric and imperial units, provided units are consistent throughout.

Input Parameters:

  • d₀: Initial diameter (m, mm, in)
  • dt: Temperature difference (°C, °F)
  • α: Linear thermal expansion coefficient (m/m°C, mm/mm°C, in/in°F)

References