1. Domestic Rainwater
Systems

2. Domestic rainwater systems
Objectives
By the end of this session you will be able to:
specify the location of running outlets on a rainwater system;
explain problems linked with changes of direction on gutters;
give details on the types of gutters and their profiles;
describe rainwater fittings and materials.

3. Running outlets on gutters
This is the part of the guttering system which acts a connection for gutter pipework at both ends and as an outlet to the downpipe.
The location of running outlets is often based on the position of the gullies for the surface water sewer which are positioned around a dwelling.
They can be identified in a building layout drawing.
Running outlet on PVCu gutter
© HOT

4. Domestic rainwater systems
Building layout drawing
Illustration no 1

5. Running outlet positions
The guttering system will be more effective with more outlets located on the guttering system as this will allow for a better balanced flow from the roof. By placing an outlet centrally rather than at the ends of a roof, it means that the outlet could accommodate a greater area of roof water run off.
The illustrations that follow show that the specific location of outlets can increase the effectiveness of a guttering system.
By dividing the expected flow rate of the roof by the flow rate of the outlet you can work out how many outlets you will need, so always check the manufacturer’s literature as flow rates for outlets vary.

6. Domestic rainwater systems
Comparison of the location of outlet positions in 1, 2 and 3 shows how the efficiency of the guttering system can be affected
Example 3 shows that the outlets would only have a ¼ of the flow to manage and as a result the risk of flooding is reduced
Running outlet options
Illustration no 2

7. Running outlet positions
By placing an outlet centrally rather than at the ends of a roof, it means that the outlet could accommodate a greater area of roof water run off.
© HOT
© HOT
Outlets located at the end of the gutter run
Outlets in middle and end of run

8. Gutters The fall of a gutter
Gutters should be laid so that they fall between 1 and 3 mm/m.
This is interpreted as a fall of 1:600 (25 mm for every 15 m).
Although gutters are designed to discharge water when installed level, a fall will greatly increase the flow capacity.
Another reason for the fall of 1:600 is that it will ensure that the gutter will not fall too low at the end run.
Brackets should be installed at a maximum of 1 m intervals to ensure the gutter can accurately contain a fall and that it does not sag when filled with water.

9. Gutters
The fall of a gutter
© HOT
© HOT
© HOT

10. Changes of direction are unavoidable and they affect the flow capacity of the gutter to discharge when the change of direction in excess of 10 °.
A 90° angle will reduce the effectiveness of the flow by 15% and every other angle reduces the efficiency of the gutter even further, even angles located near the end of the outlet. Changes of direction in effect reduce the roof area of a roof that the gutter can usefully serve.
Gutters
© HOT
© HOT

11. Gutters Try and include the following when designing a gutter system.
Straight gutter runs which offer the maximum flow rate.
Do not locate outlets near to changes of direction.
Apply the maximum fall ratio where there are lots of bends.
Install larger gutters where there are a lot of changes in direction.
Gutters
© HOT

12. Profiles and materials
Gutters have been made from a range of materials and there are different profiles for gutter systems. In the 1800s an ornamental style called OG or ogee was used as this reflected the Victorian style of the properties.
You can still buy OG style gutters as they can give a pleasing aesthetic period feel to the outside of a dwelling. They were originally made of cast iron and now you can obtain it along with other gutter profiles in PVCu.
Gutters
Ogee profile
© HOT
© HOT

13. Profiles and materials
Half round is a very common profile and is available in PVCu ,cast iron and other materials.
Gutters
Half round profile
© HOT
© HOT

14. Gutters Profiles and materials
Square is also a very common profile and is available in PVCu, cast iron and a range of other materials.
Gutters
Square profile
© HOT
© HOT

15. The British Standard for PVCu eaves guttering and fittings
is BS EN 607:2004.
BS EN :2000 covers rainwater piping systems for above ground external use.
Most of the guttering system used on domestic dwellings are made from unplasticised polyvinyl chloride (PVCu).
Gutters

16. PVCu gutters Advantages Disadvantages Ease of installation
Light and easy to handle
Low maintenance
No painting required
Economical
Corrosion free
Smooth internal bore
50 years’ life expectancy
Wood preservatives adversely affect it
Greater coefficient of thermal expansion and joint seals can be lost if expansion gap allowances are not observed during installation
Brittle in cold weather and turns soft in warmer temperatures
PVCu rainwater materials advantages and disadvantages
Table no 1

17. Gutter profiles Half round – used on many domestic properties
High capacity – used on larger and steeper roofs where high volume and velocity of water enters the gutter
Square section – good rainwater capacity. Used with square-section rainwater pipes.
Popular in 1980s and 1990s
Ogee (ornamental gutter) – popular Victorian style gutter design
Illustration no 3

18. PVCu gutter fittings Half round angle Half round gutter end
Square connecter
Half round running outlet
Half round bracket
Illustration no 4

19. All materials expand when subjected to heat and PVCu expands more than most. It has coefficient of linear expansion 0.06 mm/m/°C which means that for every degree Celsius of heat rise, 1 m of PVCu expands by 0.06 mm. This can cause joint failure on gutter connections if the manufacturer’s tolerances are not adhered to during installation.
If 1 m of gutter was exposed to a 15°C rise the gutter length would expand by 0.9m (1 × 0.06 × 15 = 0.9mm). If this temperature rise was applied to a 12 m length of gutter the length would expand by 10.8 mm (12 × 0.06 × 15 = 10.8mm).
Thermal expansion

20. Expansion gaps
Manufacturers incorporate a 10 mm expansion gap into their fittings to
allow for thermal movement which helps prevent leaks at the joints
Gutter joint with expansion marks
Illustration no 4

21. Cast iron is strong and durable but requires regular painting to help prevent corrosion. Before PVCu entered the market, cast iron was likely to be the most popular materials for gutter and rainwater pipework.
Local authorities, the National Trust and English Heritage still specify cast iron rainwater pipework.
Cast iron guttering

22. Cast iron guttering Cast iron gutter and a hopper
© HOT
© HOT
Cast iron gutter and a hopper
Cast iron gutter and bracket

23. The gutter profiles are as follows:
Half round – which is similar to the PVCu shape
Ogee section – there are several variations of this profile
Deep half round – usually found on larger buildings
Cast aluminium – replicates the profiles of cast iron and has certain advantages
Cast iron guttering

24. Cast iron gutter jointing
Cast iron guttering comes in a plain and a socket section.
The plain end is like a spigot which fits into the socket and a jointing material is inserted in between before a zinc bolt finally secures them together via a purpose-made hole in the gutter sections.
The jointing material can be linseed oil putty,
a special silicone sealant, which is usually used on new installations, or a rubber grommet which is specified by certain manufacturers.

25. Cast iron gutter jointing.
Cast iron gutter jointing
The traditional, paint and putty joint process comprises of the following:
black bitumen paint is applied to the inside of the socket and outside of the spigot;
linseed oil putty is placed in the socket and the plain gutter is then fitted;
a zinc bolt is located through a purpose-made hole and the tightened (do not over tighten or the gutter may crack);
excess putty is cleaned off with a non-abrasive item and, when clean, finally painted.

26. Gutter jointing
Sometimes it is necessary to joint gutters with different profiles and adapters are available to enable this process.
Half round to Ogee adapter in terraced house
© HOT

27. Cast iron gutters Advantages Disadvantages Strong and durable
Expensive to install and time consuming
Expensive to purchase
Regular maintenance required, such as painting
Heavy to handle
Time consuming and can be messy when jointing
Cast iron guttering advantages and disadvantages
Table no 2

28. Extruded aluminium guttering
The guttering system is manufactured on site by a specialist company and is made from coloured aluminium sheet which is
formed by a special machine transported in the back of a van. The forming machine can produce a variety of profiles.
When the aluminium is being processed strengtheners are fitted as it leaves the former to give it extra rigidity.
Continuous lengths of up to 30 m can be manufactured without the need for an expansion joint.
It is supported every 400 mm with internal brackets which add to its mechanical strength and resistance to impact form ladders, etc.

29. Extruded aluminium gutter system
Advantages
Disadvantages
Strong and durable
Lightweight
Can be installed in long lengths
Less leaks than cast iron
A range of colours and profiles
Thermal expansion minimal
Expensive to install
Not suitable for all properties where there are gutters at either side such as a mid terrace
Extruded aluminium guttering advantages and disadvantages
Table no 3

30. Calculating Diameters of Downpipes
We are going to calculate the diameter of the downpipes required for the MBEC Building.
The roof of the building has an incline of less than 10°, and is therefore classed as a flat roof however the roof is capable of collecting a lot of water, which will need to be removed as efficiently as possible.
For this example we are going to assume the following information is correct.
Velocity of water flow = 0.8m/second
Rainfall intensity = 50mm/hour
Impermeability Factor = 0.75
We just need to find out the area of the roof.

31. Calculating Diameters of Downpipes
The area of the roof is 16m x 64m giving us an area of 1024m².
We now need to use the following formula Q = VA
Where Q is the volume of flow in metres³ per second
V is the velocity of flow in metres per second
A is the cross sectional area of the pipe required in metres²
In this formula we are only able to provide a figure for V, which we know to be 0.8m/sec. To be able to calculate the area we first need to calculate Q.

32. Calculating Diameters of Downpipes
Calculating Q
Q = Area of Roof x Rainfall Intensity(m/h) x Impermeability Factor
3600 ( no. of seconds in an hour)
Q = 1024 x 0.05 x 0.75
3600
Q = m³/second
Now we know what Q is we can use the formula Q=VA to calculate the size of the pipe required.

33. Calculating Diameters of Downpipes

34. Calculating Diameters of Downpipes

35. Calculating Diameters of Downpipes
The most popular size of rainwater downpipe for houses are round pipes available in 65mm, 75mm and 100mm diameters.
The half round system of guttering is also the most popular choice of guttering for domestic buildings and comes in 100mm, 115mm, 125mm and 150mm sizes.
The 150mm diameter is most commonly used for commercial buildings.
The longest span of guttering without a downpipe must not exceed 12m.

36. Calculating Diameters of Downpipes
For the MBEC Building at a length of 64m we would require 5 downpipes, if we used 100mm diameter for each pipe we would end up with a total diameter of 500mm.
This is more than enough for efficient removal of the rainwater from the MBEC Building roof.