District Heating Temperature Capacity
Reference data and engineering information about district heating temperature capacity for thermodynamics applications.
Overview
Engineering reference data for District Heating Temperature Capacity in thermodynamics.
Key Formulas
First Law
Energy is conserved — heat added minus work done.
Ideal Gas Law
Relates pressure, volume, and temperature of an ideal gas.
Heat Transfer
Sensible heat transfer.
Carnot Efficiency
Maximum efficiency between two temperatures.
Variables
| Symbol | Description | Unit |
|---|---|---|
| Internal energy | J | |
| Heat | J | |
| Work | J | |
| Pressure | Pa | |
| Volume | m³ | |
| Temperature | K |
Data Table
Supply Temperature(°C) | Required Water Flow(liters/kW) |
|---|---|
| 90 | 28.7 |
| 100 | 21.5 |
| 112 | 16.4 |
| 120 | 14.3 |
| 133 | 11.8 |
| 150 | 9.6 |
| 180 | 7.2 |
Source: engineeringtoolbox.com
Formula: Water Flow for District Heating
For a district heating system with a constant heat demand, the required water volume flow is inversely proportional to the temperature difference between the supply and return water.
Where:
- is the volume flow rate (e.g., m³/s or L/s).
- is the required heat transfer rate (power) (e.g., kW).
- is the specific heat capacity of water (≈ 4.18 kJ/kg·°C).
- is the density of water (≈ 1 kg/L for estimation).
- is the supply water temperature.
- is the return water temperature.
Key Property: Inverse Relationship
The core principle shown in the data is that increasing the supply temperature reduces the required water flow for a given heat load. This is because the heat content of each liter of water () increases with a higher temperature difference . Therefore, fewer liters are needed to transport the same total amount of heat energy .
Note: All data in the table is calculated assuming a constant return temperature of .