Difference between revisions of "Stormwater Thermal Mitigation"

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==Overview==
Streams draining urban areas are often much warmer than those draining natural ones due to changes in surface cover and hydrology.  Urbanization increases stream temperatures by decreasing riparian shading and replacing natural landscapes with hard, dark-coloured pavements and roofs that absorb and store heat from the sun.  The added impervious cover increases the volume of heated runoff while at the same time reducing discharge of cool groundwater to streams. This heating effect is further exacerbated as runoff flows through stormwater management ponds or other impoundments, where detained water is exposed to solar warming for extended time periods between rain events. This page explores different techniques for mitigating the effects of urbanization on the stream thermal regime.
==Thermal Load==
Since stream warming is influenced by the runoff temperature and volume of runoff draining to streams, impacts are best assessed through an evaluation of thermal loads both in the stream and in runoff discharged to streams.  The thermal load is a function of the flow rate, water temperature, water density and heat capacity of water (or the energy required to increase a kg of water by 1 degree C).
'''''Thermal Load = Q x ρ x T x C'''''
{{Plainlist|1=Where:
*''Q'' = flow rate (m<sup>3</sup>/s)
*''ρ'' = water density (1000kg/m<sup>3</sup>)
*''T'' = water temperature (°C)
*''C'' = heat capacity of water (4187J/kg°C)}}
Since urban runoff volumes often increase by 2 to 5 times after development, and stormwater pond effluent temperatures are between 4 and 11°C warmer than pond influent temperatures in the summer, the overall thermal load increases to streams can be very significant ([https://sustainabletechnologies.ca/app/uploads/2019/04/Thermal-Synthesis-Final.pdf Van Seters ''et al''. 2019]).<ref>Van Seters, T., Graham, C., Dougherty, J., Jacob-Okor, C., and David, Y. 2019. Data Synthesis and Design Considerations for Stormwater Thermal Mitigation Measures. Sustainable Technologies Evaluation Program. Ontario. https://sustainabletechnologies.ca/app/uploads/2019/04/Thermal-Synthesis-Final.pdf</ref>
==Temperature Target Selection==
==Thermal Mitigation Techniques==
==Upstream of the Pond==
==Within the Pond Block==
==In the Receiving Water==
==References==

Revision as of 15:15, 12 April 2022

Overview[edit]

Streams draining urban areas are often much warmer than those draining natural ones due to changes in surface cover and hydrology. Urbanization increases stream temperatures by decreasing riparian shading and replacing natural landscapes with hard, dark-coloured pavements and roofs that absorb and store heat from the sun. The added impervious cover increases the volume of heated runoff while at the same time reducing discharge of cool groundwater to streams. This heating effect is further exacerbated as runoff flows through stormwater management ponds or other impoundments, where detained water is exposed to solar warming for extended time periods between rain events. This page explores different techniques for mitigating the effects of urbanization on the stream thermal regime.

Thermal Load[edit]

Since stream warming is influenced by the runoff temperature and volume of runoff draining to streams, impacts are best assessed through an evaluation of thermal loads both in the stream and in runoff discharged to streams. The thermal load is a function of the flow rate, water temperature, water density and heat capacity of water (or the energy required to increase a kg of water by 1 degree C).

Thermal Load = Q x ρ x T x C

Where:

  • Q = flow rate (m3/s)
  • ρ = water density (1000kg/m3)
  • T = water temperature (°C)
  • C = heat capacity of water (4187J/kg°C)

Since urban runoff volumes often increase by 2 to 5 times after development, and stormwater pond effluent temperatures are between 4 and 11°C warmer than pond influent temperatures in the summer, the overall thermal load increases to streams can be very significant (Van Seters et al. 2019).[1]

Temperature Target Selection[edit]

Thermal Mitigation Techniques[edit]

Upstream of the Pond[edit]

Within the Pond Block[edit]

In the Receiving Water[edit]

References[edit]

  1. Van Seters, T., Graham, C., Dougherty, J., Jacob-Okor, C., and David, Y. 2019. Data Synthesis and Design Considerations for Stormwater Thermal Mitigation Measures. Sustainable Technologies Evaluation Program. Ontario. https://sustainabletechnologies.ca/app/uploads/2019/04/Thermal-Synthesis-Final.pdf