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District Heating Temperature Capacity

Reference data and engineering information about district heating temperature capacity for thermodynamics applications.

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Overview

Engineering reference data for District Heating Temperature Capacity 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

Data Table

7 rows
Required water flow per unit of heat load at various supply temperatures (based on a 60°C return temperature).
Supply Temperature(°C)
Required Water Flow(liters/kW)
9028.7
10021.5
11216.4
12014.3
13311.8
1509.6
1807.2

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.

V˙=Q˙cpρ(TsTr)\dot{V} = \frac{\dot{Q}}{c_p \cdot \rho \cdot (T_s - T_r)}

Where:

  • V˙\dot{V} is the volume flow rate (e.g., m³/s or L/s).
  • Q˙\dot{Q} is the required heat transfer rate (power) (e.g., kW).
  • cpc_p is the specific heat capacity of water (≈ 4.18 kJ/kg·°C).
  • ρ\rho is the density of water (≈ 1 kg/L for estimation).
  • TsT_s is the supply water temperature.
  • TrT_r 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 (cpρ(TsTr)c_p \cdot \rho \cdot (T_s - T_r)) increases with a higher temperature difference (TsTr)(T_s - T_r). Therefore, fewer liters are needed to transport the same total amount of heat energy Q˙\dot{Q}.

Note: All data in the table is calculated assuming a constant return temperature of Tr=60°CT_r = 60°C.

Interactive Charts

Hot Water Heating System Online Design Application

References