Inspection and Maintenance: Rainwater Harvesting

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Inspection & Maintenance Guidance of Rainwater harvesting/cisterns best management practices. Rainwater harvesting is the practice of collecting, storing and making use of stormwater from roofs. Relatively clean roof runoff water is collected by eavestroughs or other types of roof drains, filtered to remove coarse debris, and conveyed to a structure where it is stored and drawn upon for purposes not requiring potable water (i.e. landscape irrigation, outdoor washing needs, fire suppression and toilet flushing (TRCA, 2018).[1]

Overview[edit]

Rainwater harvesting/cisterns uses storage structures that can be installed either:

  • Below-ground;
  • Indoors that provide a year-round water source; or,
  • Aboveground tanks and rain barrels that can only be used seasonally and must be taken out of service for the winter.

Rainwater cisterns can range in size from about 750 to 40,000 litres+ and may be constructed from fiberglass, plastic, metal or concrete. Underground cisterns are most often installed to a depth below the maximum frost penetration depth (generally 1.2 m in Southern Ontario) (Armstrong and Csathy, 1963; Ministry of Transportation, 2013)[2][3] to ensure they can be used year-round. A pump is used to deliver the stored water to the hose bibs or fixtures where it is utilized. Water that is in excess of the storage capacity of the cistern overflows to an adjacent drainage system (e.g., other BMP or municipal storm sewer) via an overflow outlet structure and pipe. Cisterns that are drawn upon for indoor water uses (e.g., toilet flushing) will also feature water level sensors and the means of adding municipal water during extended periods of dry weather or winter when stormwater does not meet the demand (i.e., make-up water supply system). They may also include in-line devices to filter stored cistern water prior to delivery at hose bibs or fixtures.

Generalized cross-section view of a rainwater harvesting system showing key components of a commercial configuration of this LID BMP (TRCA, 2018)[1].

Some of the benefits of Rainwater harvesting include:

  • The ability to reduce the quantity of pollutants and runoff being discharged to municipal storm sewers and receiving waters (i.e., rivers, lakes and wetlands);
  • Underground and indoor cisterns can be used year-round and located below parking lots, roads, plazas, parkland, landscaped areas or within buildings themselves.
  • Can reduce a large commercial building or residential home's water usage significantly if used for non-potable needs


Key components of Underground Infiltration Systems to pay close attention to are the:

Associated Practices[edit]

  • Rain Barrels Rain barrels are an above ground form of rainwater harvesting, typically used in residential settings. The precipitation flows from the roof, to the guttering and down the downspout before being diverted to the rain barrel for storage.
  • Downspout disconnection Downspout disconnections are common in many older urban centers. They require that residents retroactively disconnect their downspouts from the municipal sewer system. This is due to older sewer systems being undersized for the combined flow of sanitary waste and stormwater.
  • Blue roofs are systems that temporarily capture rainwater using the roof as storage and allow it to evaporate and/or to be used for non-potable requirements (i.e. irrigation, toilet flushing, truck washing) and ultimately offset potable water demands.

Inspection and Testing Framework[edit]

Visual indicator to be used when assessing the condition of a pretreatment device (in this case a downspout disconnection with attached filter) so that leaves and detritus from the eaves do not enter the Rainwater harvesting LID feature. Source: (STEP, 2018)[1].
Visual Indicators Framework - Rainwater Harvesting Systems

Component

Indicators

Construction Inspection

Assumption Inspection

Routine Operation Inspection

Verification Inspection
Contributing Drainage Area
CDA Condition x x x x
Inlet
Inlet/Flow spreader structural integrity x x x
Inlet/Flow spreader obstruction x x x x
Pretreatment sediment accumulation x x x
Perimeter
BMP dimensions x x x
Overflow outlets
Overflow outlet obstruction x x x x
Control structure condition x x x x
Cistern
Cistern structural integrity x x x x
Cistern sediment accumulation x x x x



Testing Indicators Framework - Rainwater Harvesting Systems

Component

Indicators

Construction Inspection

Assumption Inspection

Routine Operation Inspection

Verification Inspection
Testing Indicators
Sediment accumulation testing x x x x
Cistern pump testing x x (x)
Note: (x) denotes indicators to be used for Performance Verification inspections only (i.e., not for Maintenance Verification inspections)

Construction Inspection Tasks[edit]

Example of a polyethylene cistern being installed during construction. During construction inspections it's important to note whether or not the depths, slopes and elevations are acceptable (Photo source: Innovative Water Solutions, 2021).[6]

Construction inspections take place during several points in the construction sequence, specific to the type of LID BMP, but at a minimum should be done weekly and include the following:

  1. During site preparation, prior to BMP excavation and grading to ensure that adequate ESCs and flow diversion devices are in place and confirm that construction materials meet design specifications
  2. At completion of excavation and grading, prior to backfilling and installation of cistern and pipes to ensure depths, slopes and elevations are acceptable
  3. At completion of installation of cistern and pipes, prior to completion of backfilling to ensure slopes and elevations are acceptable
  4. Prior to hand-off points in the construction sequence when the contractor responsible for the work changes (i.e., hand-offs between the storm sewer servicing, paving, building and landscaping contractors)
  5. After every large storm event (e.g., 15 mm rainfall depth or greater) to ensure Erosion Sediment Controls (ESCs) and pretreatment or flow diversion devices are functioning and adequately maintained. View the table below, which describes critical points during the construction sequence when inspections should be performed prior to proceeding further. You can also download and print the table here
Rainwater Harvesting Systems: Construction Inspections

Construction Sequence Step & Timing

Inspection Item

Observations*
Site Preparation - after site clearing and grading, prior to BMP excavation and grading Natural heritage system and tree protection areas remain fenced off
ESCs protecting BMP layout area are installed properly
CDA is stabilized or runoff is diverted around BMP layout area
BMP layout area has been cleared and is staked/delineated
Benchmark elevation(s) are established nearby
Construction materials have been confirmed to meet design specifications
BMP Excavation and Grading - prior to backfilling and installation of cistern and conveyance pipes Excavation location, footprint, depth and slopes are acceptable
Installations of underdrains/sub-drain pipes (location, elevation, slope) are acceptable
BMP Installation – after installation of pipes/sewers, prior to backfilling Installation of structural components (i.e., pretreatment devices, inlets, cistern, overflow outlet, pump, make-up water supply and backflow preventer valve, control manhole/ access hatch) are acceptable and functioning

Routine Maintenance - Key Components and I&M Tasks[edit]

Regular inspections (twice annually, at a minimum) done as part of routine maintenance tasks over the operating phase of the BMP life cycle to determine if maintenance task frequencies are adequate and determine when rehabilitation or further investigations into BMP function are warranted.

Table below describes routine maintenance tasks for rainwater harvesting practices, organized by BMP component, along with recommended minimum frequencies. It also suggests higher frequencies for certain tasks that may be warranted for cisterns that receive flows from large roof drainage areas or roofs with mature trees near them. Tasks involving removal of debris, sediment and trash may need to be done more frequently in such contexts.

Rainwater Harvesting: Key Components, Descriptions and Routine I&M Requirements
Component Description Inspection & Maintenance Tasks (Pass) Photo Example (Fail) Photo Example
Contributing Drainage Area (CDA)

Roof area(s) from which runoff directed to the BMP originates.

  • Remove natural debris and sediment annually to biannually;
  • Trim back tree boughs that hang over the roof area to reduce maintenance needs.
CDA has not changed in size or land cover. Sediment, trash or debris is not accumulating and point sources of contaminants are not visible.
Sediment and debris is accumulating on the CDA due to deteriorating roof shingles. Eavestroughs need cleaning.
Pretreatment

Devices prevent debris and sediment from entering the BMP. Includes eavestrough or downspout screens, first flush diverters or filters on pipes leading to or from the cistern. Reduce the risk of obstructing inlets, intakes or overflow outlet pipes and excessive sediment accumulation.

  • Remove trash, debris and sediment biannually to quarterly or when the device sump is half full;
  • Measure sediment depth or volume during each cleaning, or annually to estimate accumulation rate and optimize frequency of maintenance.
The pretreatment filter of the cistern is free of sediment and debris.
The pretreatment filter on the roof downspout is partially covered by debris which could prevent stormwater from freely entering the BMP (Source: DMR).
Inlets

Pipes connected to eavestroughs or roof drains that deliver water to the BMP. May also include a pipe connected to the municipal water supply line for maintaining cistern water level during dry weather.

  • Check for obstructions and remove any debris or sediment annually to biannually;
  • For outdoor above-ground cisterns and rain barrels, inlets need to be disconnected in the late fall/early winter, prior to the onset of freezing air temperatures;
  • Reconnect outdoor above-ground cisterns to the roof drainage area in the spring once air temperature remains above freezing.
Inlet pipe and couplings are securely connected to the CDA and cistern. (Source: Lake County SMC)
The roof downspout is disconnected from the eavestrough, preventing runoff from entering the cistern.
Access Hatch

Hatch, manhole or lid that provides access to the interior of the water storage structure.

  • Inspect for damage, obstruction and accessibility annually.
The access hatch of this cistern is accessible with ladder rungs in place.
The access hatch of this cistern was paved over with concrete and ladder rungs are missing which prevents safe entry for inspection and maintenance tasks. (Source: Miles Golding).
Cistern or rain barrel

The water storage structure (e.g., concrete vault, fiberglass, plastic or metal tank, rain barrel).

  • Inspect for damage or leaking annually;
  • Drain and remove accumulated sediment as needed (annually at a minimum).
There are no cracks or leaks visible in the cistern structure.
A section of sealing tape over two pieces of the concrete cistern structure is displaced, raising the potential for leaks in the future.
Pump

Pressurized device used to deliver stored rainwater to the hose bibs.

  • Inspect and test for proper function annually.
Installation of structural components and current operating level are acceptable and functioning in clean and easily accessible condition as seen here (Photo Source: Riada Sales Inc., 2022)[7]
With prolonged usage, the pump capacity declines, causing a reduction in flow rate overall. If the pump is not creating sufficient pressure, and the flow rate is below the design specification, servicing of the pump by a skilled technician should be scheduled (Photo Source: Rapid Plumbing Group Pty Ltd., 2022).[8]
Filter

Cisterns may include an in-line filter device on the intake pipe or prior to delivery of rainwater to hose bibs.

  • Remove debris and sediment biannually to quarterly or as directed by the system manufacturer.
Very little sediment and no coarse debris has accumulated on the bottom of the cistern and the sediment is not at the level of the distribution system intake structure.
Enough sediment has accumulated in the cistern to cause water delivered from the distribution system to be turbid and discoloured when cistern water levels are low. Intake filyrt must be checked and changed.
Overflow Outlet

Pipe connected to the cistern or rain barrel that conveys overflows to another drainage system (e.g., municipal storm sewer or other BMP).

  • Check for obstructions and remove any debris or sediment annually to biannually.
The overflow outlet pipe diameter matches what was specified in the final design and is free of damage and obstruction.
The overflow outlet pipe on this rain barrel is undersized and obstructed which impairs its function to safely convey excess water from the BMP. (Source: Melinda Webb)

Tips to Preserve Basic BMP Function[edit]

  • Routinely check the water delivered to hose bibs or fixtures for turbidity or discolouration which could indicate excessive sediment accumulation in the cistern or failure of pretreatment devices or filters.
  • Include a filtration device to treat stored water prior to delivery to hose bibs or fixtures as part of the intake/distribution system and clean filters at the same frequency as pretreatment devices.
  • If the overflow outlet discharges at grade, the pipe opening should be covered with a coarse screen to prevent entry by insects and animals.
  • Provide a means of draining the cistern by gravity to make inspection and maintenance work that requires drainage of the BMP easier to perform.
  • Remove accumulated sediment from a large cistern using a pressure washer or hydro-vac truck equipped with a JetVac nozzle to scour and direct sediment to a collection point for removal by vacuuming; for small cisterns, a garden hose and wet shop vacuum may be used.

Rehabilitation & Repair[edit]

Table below provides guidance on rehabilitation and repair work specific to rainwater harvesting systems and rain barrels organized according to BMP component. For more detailed guidance on troubleshooting rainwater harvesting systems refer to Ontario Guidelines for Residential Rainwater Harvesting Systems - Handbook (Despins, 2010)[9] and the Canadian Guidelines for Residential Rainwater Harvesting Systems Handbook, developed by the Canadian Mortgage and Housing Corporation (CHMC) (Despins, 2012)[10]

Technician conducting FIT work to ensure cistern tank is in optimal working order. (Photo Source: Pristine Water Systems, 2017)[11]
Rainwater Harvesting Systems: Key Components, Typical Issues and Rehabilitation Requirements
Component Problem Rehabilitation Tasks
Inlets

Pipes or fittings are damaged or displaced.

  • Schedule repairs.
Ice is accumulating and obstructing inflow to BMP.
  • Schedule installation of heat trace wire along eavestroughs, around roof drains and in aboveground pipes, or disconnect the system during winter.
Cistern

Cracks are visible or seals between joints in the structure are leaking.

  • Schedule repairs with oversight by the product manufacturer/vendor.
Cistern has reached 40 years of age and is due for replacement.
  • Replace cistern with new one that meets design specifications.
Overflow Outlet

Overflow outlet pipe is obstructed by trash, debris or sediment.

  • Schedule drain snaking service or pressure/vacuum truck to remove the obstruction.
Make-up water supply

System is malfunctioning (e.g., tops up cistern water level when unnecessary or fails to top up when needed).

  • Schedule FIT work to determine the cause of system malfunction with oversight by the product manufacturer/vendor or a licensed plumber and electrician.
Pump

Pump is not delivering water to fixtures or not providing adequate water pressure.

  • Schedule FIT work to determine the cause of system malfunction with oversight by the product manufacturer/vendor or a licensed plumber and electrician.

Inspection Time Commitments and Costs[edit]

Life cycle cost estimates are based on two design variations that can be used year-round: underground concrete cistern; and indoor plastic cistern systems. For each design variation, life cycle costs can be found in the Low Impact Development (LID) Stormwater Management Practice Inspection and Maintenance Guide

General time commitments and costs for inspection of rainwater harvesting features features with partial infiltration (in 2016 $ figures) (TRCA, 2018)[1].
Per-task cost estimates for maintenance and rehabilitation of rainwater harvesting features features with partial infiltration (in 2016 $ figures) (TRCA, 2018)[1].
Construction and life cycle cost estimates for rainwater harvesting features features with partial infiltration (in 2016 $ figures) (TRCA, 2018)[1].


Estimates of the life cycle costs of inspection and maintenance have been produced using the latest version of the LID Life Cycle Costing Tool for two design variations (underground concrete cistern; and indoor plastic cistern systems) to assist stormwater infrastructure planners, designers and asset managers with planning and preparing budgets for potential LID features.

Assumptions for the above costs and the following table below are based on the following:

  • For rainwater cisterns it is assumed that no rehabilitation work will be needed to maintain acceptable storage and drainage performance over a 50 year period of operation (40 for plastic cisterns), given that pretreatment devices are in place and are being adequately maintained. The annual average maintenance cost value represents an average of routine maintenance tasks, as outlined in Rainwater Harvesting: Key Components, Descriptions and Routine I&M Requirements table above. All cost value estimates represent the NPV as the calculation takes into account average annual interest (2%) and discount (3%) rates over the evaluation time periods.
  • Life cycle cost estimates have been generated for two design variations that can be used year-round: underground concrete cistern; and indoor plastic cistern systems. For each design variation, life cycle cost estimates have been calculated for two level-of-service scenarios: the minimum recommended frequency of inspection and maintenance tasks in the Per-task cost estimates for maintenance and rehabilitation of rainwater harvesting features table above to provide an indication of the potential range. Only the indoor plastic cistern requires rehabilitation within the 50 year evaluation period. At year 40 it is assumed the plastic cistern is replaced with anew one.
  • For all scenarios, the roof area that drains into the rainwater harvesting cistern is 2,000 m2. The water storage capacity of the cistern is assumed to be 23,000 L. Both cistern systems include a dual plumbing distribution system, an 81.2 LPM submersible pump and a 439 L expansion tank. The systems also include a float switch to prevent the pump from dry running, a top-up float switch and associated wring, a solenoid valve, air gap to prevent backflow, as well as backflow preventer at the premise boundary, a water meter and a water hammer arrestor. The rainwater is used for toilet flushing of 260 occupants. It is assumed that two hose bibs are used on average 14 minutes per day from April to September. The underground concrete cistern is installed adjacent to the building. The plastic cistern is stored inside the building, so no excavation is required to install/uninstall it.
  • Estimates of the life cycle costs for the two rainwater cistern system design variations in Canadian dollars per unit CDA ($/m2) are presented in the table below. The LID Life Cycle Costing Tool allows users to select what BMP type and design variation applies, and to use the default assumptions to generate planning level cost estimates. Users can also input their own values relating to a site or area, design, unit costs, and inspection and maintenance task frequencies to generate customized cost estimates, specific to a certain project, context or stormwater infrastructure program.
  • For indoor plastic cistern systems it is assumed that replacement of the cistern itself is needed once it reaches 40 years of age. Replacement of the cistern is assumed to typically involve the following tasks and associated costs:
    • Dismantle all portions of the system within or connected to the cistern;
    • Replace the plastic cistern with a new one that meets design specifications;
    • Reassemble the system, re-using existing components;
    • Construction and Assumption inspection work associated with the rehabilitation work (including cistern pump testing).


Life cycle cost estimates for both underground (buried) concrete cisterns and indoor plastic cisterns under minimum and high frequency scenarios (in 2016 $ figures)[1].

Notes:

  1. Estimated life cycle costs represent NPV of associated costs in Canadian dollars per squaremetre of CDA ($/m2).
  2. Average annual maintenance cost estimates represent NPV of all costs incurred over the time period and do not include rehabilitation costs.
  3. Over a 50 year evaluation period, average annual maintenance cost estimates for the High Frequency maintenance scenario are 59% and 56% higher than the Minimum Recommended Frequency maintenance scenario for underground concrete cistern and indoor plastic cistern systems respectively.
  4. Rehabilitation costs for the indoor plastic cistern system (i.e., replacing the cistern structure) are estimated to be 9.67% of the original construction costs, regardless of the maintenance frequency.
  5. Maintenance costs over a 25 year time period for underground concrete cistern systems are estimated to be 45.8% of the original construction cost for the Minimum Recommended Frequency maintenance scenario, and 89.4% for the High Frequency maintenance scenario.
  6. Maintenance costs over a 25 year time period for indoor plastic cistern systems are estimated to be 47.7% of the original construction cost for the Minimum Recommended Frequency maintenance scenario, and 98.0% for the High Frequency maintenance scenario.
  7. Maintenance costs over a 50 year time period for underground concrete cistern systems are estimated to be 0.918 times the original construction cost for the Minimum Recommended Frequency maintenance scenario, and 1.59 times for the High Frequency maintenance scenario.
  8. Maintenance costs over a 50 year time period for indoor plastic cistern systems are estimated to be 1.07 times the original construction cost for the Minimum Recommended Frequency maintenance scenario, and 1.84 times for the High Frequency maintenance scenario.

Inspection Field Data Sheet[edit]

Feel free to download (downward facing arrow on the top righthand side) and print (Pinter emoticon on top right hand side) the following Rainwater Cisterns/Harvesting Inspection Field Data Form developed by TRCA, STEP and its partners for the Low Impact Development Stormwater Management Practice Inspection and Maintenance Guide[12].

The 3 page document prompts users to fill out details previously mentioned above on this page in other sections about various zones associated with Rainwater harvesting systems and rain barrels, along with other associated features (i.e. inlets, CDA, pretreatment, outlets, access hatches, etc.) and describe why each area is a pass or fail, and if remediate action is required and under what timeframe it would be completed by. Furthermore, the forms prompt the reviewer to determine what type of inspection is being conducted for the feature in question: Construction (C), Routine Operation (RO), Maintenance Verification (MV), or Performance Verification (PV).

An access hatch to help make inspecting and maintaining rainwater cisterns easier to do for technicians or hired professionals. (Photo Source: TRCA).

load PDF

References[edit]

  1. 1.0 1.1 1.2 1.3 1.4 1.5 1.6 TRCA. 2018. Fact Sheet - Inspection and Maintenance of Stormwater Best Management Practices: Rainwater Cisterns. https://sustainabletechnologies.ca/app/uploads/2018/02/Rainwater-Cisterns-Fact-Sheet.pdf
  2. Armstrong, M. D., & Csathy, T. I. 1963. Frost design practice in Canada-and discussion. Ontario Department of Highways. https://onlinepubs.trb.org/Onlinepubs/hrr/1963/33/33-008.pdf
  3. Ministry of Transportation. 2013. Pavement Design and Rehabilitation Manual. Second Edition. IBSN: 978-1-4435-2873-3. Published: March 2013. http://www.bv.transports.gouv.qc.ca/mono/1165561.pdf
  4. Armstrong, M. D., & Csathy, T. I. 1963. Frost design practice in Canada-and discussion. Ontario Department of Highways. https://onlinepubs.trb.org/Onlinepubs/hrr/1963/33/33-008.pdf
  5. Ministry of Transportation. 2013. Pavement Design and Rehabilitation Manual. Second Edition. IBSN: 978-1-4435-2873-3. Published: March 2013. http://www.bv.transports.gouv.qc.ca/mono/1165561.pdf
  6. Innovative Water Solutions. 2021. Underground Polyethylene Cisterns - An Inexpensive Option for Buried Tanks. Accessed 08 August, 2022. https://www.watercache.com/portfolio/underground-poly-tanks
  7. Riada Sales Inc. 2022. Rainwater Harvesting Systems. System shown from QuantumFlowTM. Accessed 15 August 2022. https://riada.ca/rainwater-harvesting-systems/
  8. Rapid Plumbing Group Pty Ltd. 2022. Penrith Rainwater Services - Rainwater tanks and pumps. Accessed 15 August 2022. https://www.rapidplumbinggroup.com.au/penrith-plumber/rain-water-tank-pump-services/
  9. Despins. 2010. Ontario Guidelines for Residential Rainwater Harvesting Systems - Handbook. Accessed August 15, 2022. https://www.harvesth2o.com/adobe_files/ONTARIO_RWH_HANDBOOK_2010.pdf
  10. Despins. 2012. Canadian Guidelines for Residential Rainwater Harvesting Systems Handbook. Accessed August 15, 2022. https://www.crd.bc.ca/docs/default-source/water-pdf/cmhcrainwaterhandbook.pdf?sfvrsn=67aa96c9_2.
  11. Pristine Water Systems. 2017. When is the best time to clean my Rainwater Tank? Accessed 16 August 2022. https://www.pristinewatersystems.com.au/2017/02/20/best-time-to-clean-rainwater-tank/
  12. STEP. 2016. Low Impact Development Stormwater Management Practice Inspection and Maintenance Guide. https://sustainabletechnologies.ca/app/uploads/2016/08/LID-IM-Guide-2016-1.pdf