The head (measured in
metres(m)) is the vertical drop from the top of system (where the water
enters your pipe/penstock) to the bottom (where it is released). Head
should not be confused with the distance between the top and bottom of the
system (which should be kept to a minimum). It is the difference in
height, the drop, that counts. The greater the head, the higher the
potential power. There are several ways you might measure the head. You
could check an ordinance survey map for contour lines. You could measure
the straight line distance between top and bottom and the angle between
the two and use trigonometry. You could even borrow an altimeter (some
gimmicky watches have them).
The flow (measured in litres per
second (l/s)), is the volume of water which flows past any given point in
the system within the period of one second. It needs to be measured before
the turbine is in place in order to find the potential power because the
flow will be reduced when it is fitted. The greater the flow, the higher
the potential power. There are several ways to measure flow but the
simplest is to use a bucket of a known capacity and time how long it takes
to fill. Eg. If it take 5 seconds to fill a 10 litre bucket you have 2
litres per second.
Calculating the power
(measured in watts (W)), is done by multiplying the head and flow by the
force of gravity (around 9.8 m/s/s which you can't easily change
significantly without leaving the planet). For ease of calculation you
could use 10 m/s/s as the force of gravity - no one will notice (unless
they are very unfit).
| To calculate the
potential power..
head (m) x flow
(l/s) x gravity (10) = power available (w)
For example, if you
have just 0.25 l/s and a head of 20 metres, the power available
would be 20 x 0.25 x 10 = 50 watts
Note: What
you consider practical or a useful amounts of power, may well differ
from other peoples ideas so bear that in mind when you see figures
sometimes quoted for minimum usable head and flow. If all you want
is to provide is a trickle charge to keep a battery toped up when
not in use for long periods of time, you might be happy with a
fraction of a watt from a home made system rather than buy expensive
solar panels or have to keep buying new batteries.
|
The main parts of a hydro system are the penstock and the turbine. The
penstock is any artificial method by which you get water to your turbine
from the highest point in your system with the minimum of obstruction and
resistance. Penstock may be in the form of pipes or an artificial channel
but sometimes the landscape may have provided a natural solution.
Other factors that effect the amount of power available include the
resistance experienced by the water while on its way to your turbine which
is directly proportional to the length of your penstock. If you are using
pipe it is important to use a large enough diameter and keep it as short
as possible while still providing the amount of head you want. Avoid any
sharp bends or joins etc.
The type of turbine you use will dictate how much of the available
power you can actually provide to the generator and the efficiency of the
generator will dictate the amount of electrical power provided. You will
probably get less than half the available power. Your losses don't end
there. If your turbine is located a great distance from the site you plan
to use you power you may also have transmission losses in the cable. But
what the hell, even with the losses, something is better than nothing.
This page will
be updated to include;
- Information on the
use of pumps as turbines,
Our first system used a rotary pump as a
turbine. These are fairly easy and cheap to obtain and can provide quite
high efficiencies. Information about suitable types of pump can be
obtain from a book produced by Intermediate Technology (see below).
- Possible designs
for building turbines from scratch
We have build a pelton wheel from
flat plate aluminium. Other ideas include using teaspoons or casting
individual pelton cups and fitting them onto a hub. If you want to chat
about these ideas, please do get in touch.
- The reuse of impellers and
small propellers from model boats etc.
Just an ideal but it should
work. There is a name for this but I can't recall it. Coaxial / In flow
?
Basically you would place a propeller like turbine inside a curved
section of pipe so that the shaft could exit the pipe and be attached to
a generator.
- How to build a filter
Our
first system failed fairly often due to a poorly designed filter. A
system using a pump as an turbine will need a good filter. Our latest
system doesn't suffer from the same problem since small object can not
jam the turbine.
- The use of DC motors as
generator
Permanent DC motors are a cheap and easy source of
generators. They work in the same way as a dynamo. There are more
efficient ways of doing this but this is certainly the easiest. DC
motors can be found in scraped cars (fan motor etc.). Turn them fast
enough and you've got power.
- How to generate AC and why you
might want to
There are reasons why you might want to generate AC
even if you only use 12v DC systems. High voltage AC can be transferred
long distances in thin cable while much thicker cable would be required
for low voltage DC. AC can be stepped up or down easily and efficiently
using transformers. The same is not true of DC. For these reasons it
often makes sense to start with AC. Induction motors are a very common
form of AC motor that can be obtained very cheaply. They come in a
variety of sizes and can be made to act as generators. See the book from
Intermediate Technology to find out how to do this (and then let us
know).
Keep It Simple Stupid: Don't forget that you don't have to
produce electricity when you need power. When it is possible to do so, you
will find it more efficient to use the available mechanical power
directly. For example; powering machinery such as a saw mill, grinder,
stone polisher etc.
For more detailed information on the subject of small scale hydro power
you might like to consult these outside links:
The Micro Hydro Centre - Research, information and
development projects.
Pico hydro website - Articles, newsletter, useful
guides.
Hydropower literature - A comprehensive list of books on
the subject. We can't recommend any specifically because we haven't got
read any yet, however we are sure that the books published by Intermediate Technology
on the use of pump as turbines and the use of induction motors as generators both sound very useful and
would be a great addition to our library (hint hint).
| Note: If you
are planning on setting up a hydro power system in the United
Kingdom you may require a water extraction license under the Water
Resources Act 1991. There are exceptions from the annual fee based
on the power generating capacity of the system and also on the level
of water use and type of installation. To find out more, contact the
Environment Agency. Similar legal considerations may apply in other
countries. |
See also: General
information about hydro electric power
Our own micro
hydro system at Steward Wood
Last updated 18th March 2002