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Gravity Heating Systems

Reference data and engineering information about gravity heating systems for material properties applications.

gravityheatingsystems

Overview

Engineering reference data for Gravity Heating Systems in material science and properties.

Key Formulas

Stress

σ=FA\sigma = \frac{F}{A}

Force per unit area.

Strain

ε=ΔLL0\varepsilon = \frac{\Delta L}{L_0}

Change in length per original length.

Hooke's Law

σ=Eε\sigma = E \varepsilon

Stress proportional to strain in elastic region.

Thermal Expansion

ΔL=αL0ΔT\Delta L = \alpha L_0 \Delta T

Length change due to temperature.

Variables

SymbolDescriptionUnit
σ\sigmaStressPa
ε\varepsilonStrain
EEYoung's modulusPa
α\alphaThermal expansion coefficient1/°C
ΔT\Delta TTemperature change°C

Gravity Circulating Pressure Data

The circulating pressure in a self-circulation heating system depends on both the flow and return temperatures. The following table shows the available pressure (in Pa per meter of circulating elevation) for various temperature combinations.

6 rows
Circulating pressure in Pa (N/m²) per meter of circulating elevation for gravity heating systems with operating temperatures 50–95°C
Return Temperature(°C)
Flow 40°C(Pa/m)
Flow 50°C(Pa/m)
Flow 60°C(Pa/m)
Flow 70°C(Pa/m)
Flow 80°C(Pa/m)
Flow 90°C(Pa/m)
4004189143203267
50048101161225
60054113177
70059123
80064
900

Source: engineeringtoolbox.com

System Properties

Thermal Expansion: The thermal expansion of water is approximately 4.2% when heated from 4°C to 100°C. This density difference is the driving force behind gravity circulation systems.

Operating Principles:

  • Self-circulation systems rely on natural density differences between hot supply water and cooler return water
  • No mechanical pump is required; circulation is driven by the "stack effect"
  • Greater temperature differences and greater radiator elevation above the boiler increase the circulating pressure and flow rate

Design Considerations:

  • Typical operating temperature range: 50°C to 95°C
  • Circulating pressure increases with larger temperature differentials (ΔT)
  • System performance is sensitive to pipe sizing and circuit resistance

Interactive Charts

Gravity heating system

References