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HydroGrown
Hydroponics Ltd.
Copyright © 2006 |
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F.A.Q. TOPICS
General |
Hydroponics |
Lighting |
Growing Medium |
Propagation |
Plants |
Pest Control |
Climate Control |
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Topic: Hydroponics F.A.Q.
Quick Links:
|
Why
should I use Hydroponics? |
|
What is pH, and how can I test
for it? |
|
Should I top-off my reservoir
with plain water or nutrient
solution? |
|
Common nutrient disorders in
hydroponic systems |
|
pH and PPM values for different
plants (hydroponic gardening
only) |
|
What kind of maintenance is
involved with a hydroponic
system? |
|
What are the advantages and
disadvantages to using
hydroponics and growing indoors? |
|
How often should you change your
reservoir? |
|
What does an air stone do? |
|
What size water pump do I need
for a reservoir that hold "x"
number of gallons? |
| |
| |
|
Why
should I use Hydroponics? |
|
Hydroponic
gardening is easy and fun once
the concept and principles are
understood. There are a few
basic rules that must be
followed to make a good
hydroponic system productive.
First, let's look at how and why
hydroponics works. In the basic
hydroponic system, the inert
soilless medium contains
essentially no nutrients of its
own. All the nutrients are
supplied by the nutrient
(fertilizer) solution. This
solution passes over the roots
or floods around them at regular
intervals, later draining off.
The extra oxygen around the
roots is able to speed the
plants' uptake of nutrients.
Plants grow faster
hydroponically because they are
able to assimilate nutrients
faster. They are able to take in
food as fast as they are able to
utilize it. In soil, as in
hydroponics, the roots absorb
nutrients and water; even the
best soil rarely contains as
much oxygen as a soilless
hydroponic medium.
Hydroponics works well for
horticulturists who are willing
to spend a few extra minutes a
day in their garden. The garden
requires extra maintenance.
Plants grow faster and there are
more things to check. In fact,
some people do not like
hydroponic gardening because
plants grow too fast and require
additional care.
Hydroponic gardening can become
overwhelming for the novice
gardener if too complex of a
system is implemented at first
if you are a novice gardener and
want to garden hydroponically,
try setting up a basic system.
Once you have gained experience
and feel comfortable with
hydroponics, move to a more
elaborate system. Remember, if
you buy all the new little
hydroponic garden gadgets
available, you may start more
projects than you can manage
effectively. If you are
contemplating constructing and
inventing your own unit, get
your hands wet with a tried and
true system first it will take a
month or two to work out most of
the bugs in a homemade unit.
Hydroponic gardening is exacting
and not as forgiving as soil
gardening. The soil works as a
buffer for nutrients and holds
them longer than the inert
medium of hydroponics. Some very
advanced hydroponic systems do
not even use a soilless mix. The
roots are suspended in the air
and misted with nutrient
solution. The misting chamber is
kept dark so algae does not
compete with roots. This form of
hydroponics is called aeroponics.
Plants properly maintained,
grown hydroponically under HID
lamps tend to grow more lush
foliage and at a faster rate
than plants grown in soil. The
real benefit with hydroponics is
realized later in the plant's
life. When roots are restricted
and growth slows in
containerized plants,
hydroponically grown plants are
still getting the maximum amount
of nutrients.
The above is an excerpt from
George Van Patten's book, "New
Revised Gardening Indoors".
What is pH, and how can I test
for it?
pH stands for "Potential of Hydrogen" and is
the symbol for the hydrogen ion
(H+) in liquids. pH has a range
from 0 (acidic) - 14 (alkaline),
with 7 being neutral. For
hydroponics we are aiming for a
pH between 5.5 to 6.2 (slightly
acidic); this is suitable for
most hydroponic crops. For soil,
we want the pH a little higher
but still slightly acidic;
around 6.0 to 6.5. Ensuring that
the pH remains within this range
will help maintain good plant
health. Keeping the pH in this
range ensures that nutrients are
readily available to the plant.
Once the grower goes above or
below this optimal range certain
nutrients start becoming
unavailable to the plant (e.g.
iron deficiencies will appear at
a pH of 6.5 and above).
All hydroponic growers need to
test the pH of their nutrient
solution for successful growing.
The pH of a solution can be
tested using a standard pH test
kit (sample vial with drops of
indicator solution), litmus test
strips, or a digital pH meter.
Litmus paper and standard test
kits are cheap and easy to use;
however, the degree of accuracy
isn't very high. Digital pH
meters, although more expensive
than the alternatives, are easy
to use and very accurate.
Should I top-off my reservoir
with plain water or nutrient
solution?
In the summer
or in hot grow rooms, plants, in
general, will take up more water
than nutrients, thus causing the
nutrient solution to become more
salty. In the winter time or in
cooler grow rooms, the opposite
will occur. Nutrient uptake will
also be determined by the type
of crop being grown e.g.,
tomatoes are heavier feeders
than lettuce. It is extremely
important that the grower has
both a TDS meter and a pH meter
and that regular testing on the
nutrient solution is carried out.
If the grower notices after a
few days that the ppm level in
the reservoir is high and the
water level has decreased than
the grower should top up their
reservoir with either plain
water or a weak nutrient
solution until the optimum ppm
level is reached. If the grower
has noticed a drop in ppm levels
then a full strength nutrient
solution should be used to top
off the reservoir. Another
factor to consider is the source
water. You will generally find
that if you are not using
reverse osmosis water, you will
usually have to top-off with
plain water, since tap water has
a lot of sodium and minerals
that increase the ppm levels.
Common nutrient disorders in
hydroponic systems
Nutrient Disorders
Nutrient disorders are caused by
too much or too little of one or
several nutrients being
available. These nutrients are
made available between a pH
range of 5 and 7 and a total
dissolved solids (TDS) range of
800 to 3000 PPM. Maintaining
these conditions is the key to
proper nutrient uptake.
Nutrients
Over twenty elements are needed
for a plant to grow. Carbon,
hydrogen and oxygen are absorbed
from the air and water. The rest
of the elements, called mineral
nutrients, are dissolved in the
nutrient solution. The primary
or macro-nutrients (nitrogen
(N), phosphorus (P) and
potassium (K)) are the elements
plants use the most. Calcium
(Ca) and magnesium (Mg) are
secondary nutrients and used in
smaller amounts. Iron (Fe),
sulfur (S), manganese (Mn),
boron (B), molybdenum (Mo), zinc
(Zn) and copper (Cu) are
micro-nutrients or trace
elements. Trace elements are
found in most soils. Rockwool
(hydroponic) fertilizers must
contain these trace elements, as
they do not normally exist in
sufficient quantities in
rockwool or water. Other
elements also play a part in
plant growth. Aluminum,
chlorine, cobalt, iodine,
selenium, silicon, sodium and
vanadium are not normally
included in nutrient mixes. They
are required in very minute
amounts that are usually present
as impurities in the water
supply or mixed along with other
nutrients. The above nutrients
are mixed together to form a
complete plant fertilizer. The
mix contains all the nutrients
in the proper ratios to give
plants all they need for lush,
rapid growth. The fertilizer is
dissolved in water to make a
nutrient solution. Water
transports these soluble
nutrients into contact with the
plant roots. In the presence of
oxygen and water, the nutrients
are absorbed through the root
hairs.
*NOTE: The nutrients must be
soluble (able to be dissolved in
water) and go into solution.
Nitrogen
(N) is primary to plant growth.
Plants convert nitrogen to make
proteins essential to new cell
growth. Nitrogen is mainly
responsible for leaf and stem
growth as well as overall size
and vigor. Nitrogen moves easily
to active young buds, shoots and
leaves and slower to older
leaves. Deficiency signs show
first in older leaves. They turn
a pale yellow and may die. New
growth becomes weak and spindly.
An abundance of nitrogen will
cause soft, weak growth and even
delay flower and fruit
production if it is allowed to
accumulate.
Phosphorus
(P) is necessary for
photosynthesis and works as a
catalyst for energy transfer
within the plant. Phosphorus
helps build strong roots and is
vital for flower and seed
production. Highest levels of
phosphorus are used during
germination, seedling growth and
flowering. Deficiencies will
show in older leaves first.
Leaves turn deep green on a
uniformly smaller, stunted
plant. Leaves show brown or
purple spots. NOTE: Phosphorus
flocculates when concentrated
and combined with calcium.
Potassium
(K) activates the manufacture
and movement of sugars and
starches, as well as growth by
cell division. Potassium
increases chlorophyll in foliage
and helps regulate stomata
openings so plants make better
use of light and air. Potassium
encourages strong root growth,
water uptake and triggers
enzymes that fight disease.
Potassium is necessary during
all stages of growth. It is
especially important in the
development of fruit. Deficiency
signs of potassium are: plants
are the tallest and appear
healthy. Older leaves mottle and
yellow between veins, followed
by whole leaves that turn dark
yellow and die. Flower and fruit
drop are common problems
associated with potassium
deficiency. Potassium is usually
locked out by high salinity.
Magnesium
(Mg) is found as a central atom
in the chlorophyll molecule and
is essential to the absorption
of light energy. Magnesium aids
in the utilization of nutrients,
neutralizes acids and toxic
compounds produced by the plant.
Deficiency signs of magnesium
are: Older leaves yellow from
the center outward, while veins
remain green on deficient
plants. Leaf tips and edges may
discolor and curl upward.
Growing tips turn lime green if
the deficiency progresses to the
top of the plant.
Calcium
(Ca) is fundamental to cell
manufacture and growth. Soil
gardeners use dolomite lime,
which contains calcium and
magnesium, to keep the soil
sweet or buffered. Rockwool
gardeners use calcium to buffer
excess nutrients. Calcium moves
slowly within the plant and
tends to concentrate in roots
and older growth. Consequently
young growth shows deficiency
signs first. Deficient leaf
tips, edges and new growth will
turn brown and die back. If too
much calcium is applied early in
life, it will stunt growth as
well. It will also flocculate
when a concentrated form is
combined with potassium.
Sulphur
(S) is a component of plant
proteins and plays a role in
root growth and chlorophyll
supply. Distributed relatively
evenly with largest amounts in
leaves which affects the flavor
and odor in many plants. Sulphur,
like calcium, moves little
within plant tissue and the
first signs of a deficiency are
pale young leaves. Growth is
slow but leaves tend to get
brittle and stay narrower than
normal.
Iron
(Fe) is a key catalyst in
chlorophyll production and is
used in photosynthesis. A lack
of iron turns leaves pale yellow
or white while the veins remain
green. Iron is difficult for
plants to absorb and moves
slowly within the plant. Always
use chelated (immediately
available to the plant) iron in
nutrient mixes.
Manganese
(Mg) works with plant enzymes to
reduce nitrates before producing
proteins. A lack of manganese
turns young leaves a mottled
yellow or brown.
Zinc
(Z) is a catalyst and must be
present in minute amounts for
plant growth. A lack of zinc
results in stunting, yellowing
and curling of small leaves. An
excess of zinc is uncommon but
very toxic and causes wilting or
death.
Copper
(C) is a catalyst for several
enzymes. A shortage of copper
makes new growth wilt and causes
irregular growth. Excesses of
copper causes sudden death.
Copper is also used as a
fungicide and wards off insects
and diseases because of this
property.
Boron
(B) is necessary for cells to
divide and protein formation. It
also plays an active role in
pollination and seed production.
Molybdenum
(Mo) helps form proteins and
aids the plant's ability to fix
nitrogen from the air. A
deficiency causes leaves to turn
pale and fringes to appear
scorched. Irregular leaf growth
may also result.
The above text is an excerpt
from George Van Patten's
excellent book "Gardening
Indoors with Rockwool"
pH and PPM values for different
plants (hydroponic gardening
only)
A few
facts about PPM, TDS, EC, cF,
and pH
1. Electro-Conductivity (EC) or
Conductivity Factor (cF) can be
expressed as either milliSiemens
(mS), cF, or parts per million
(PPM) 1 mS = 10cF = 700ppm.
2. The pH and
electro-conductivity values
specified here are given as a
broad range. It should be noted
that specific plant requirements
will vary according to regional
climatic conditions, and from
season to season within that
region.
3. As a general rule, plants
will have a higher nutrient
requirement during cooler
months, and a lower requirement
In the hottest months.
Therefore, a stronger nutrient
solution should be maintained
during winter, With a weaker
solution during summer when
plants take up and transpire
more water than nutrients.
4. KNOW YOUR CROP. Plant EC or
cF may vary according to the
stage of growth. For example,
cucumber prefer 20cF when
establishing, and 25cF after the
first harvest. Between 5 and 7
weeks after first harvest, the
optimum cF is 17.
5. The nutrient solution should
be discarded at regular
intervals. Should there be a
requirement to flush the growing
bed, the system should be
flushed with fresh nutrients
(run-to-waste) rather than water
to avoid starving or stressing
plant.
The following are links to
charts for pH / PPM / EC for
different plants grown in
hydroponics.
What kind of maintenance is involved
with a hydroponic system?
As with soil-based production,
producing crops in hydroponic systems always
requires maintenance. The following list may
seem like a lot of work; however, as you become
experienced most tasks and checks will only take
a few minutes each day.
Daily
 | Check reservoir for water
levels, pH and TDS fluctuations. |
| Check grow room temperatures and humidity
percentages. |
| If you use CO2, the CO2 system should be checked
to ensure that it is working correctly. |
|
Check watering system. If a pump fails it should
be replaced immediately. If drippers are blocked
they should be cleaned or replaced immediately. |
| Check plants for disease and insect infestations.
It is always best to stop disease and insect
outbreaks early. The longer an infestation is
left the more difficult it will be to cure,
yield losses will be high and crop failures are
possible. |
| Check plants for leaf discoloration and
deformities that may be caused by such problems
as nutrient deficiencies or nutrient burn (over
feeding), as well as leaf curl from lights being
to close. |
| Crop hygiene is extremely important. Cut off and
discard diseased leaves. If a plant is badly
diseased, it is always better to throw out one
or two plants to control disease outbreaks than
it is to destroy a complete crop. The same
applies to insect infestations, especially
spider mites. |
| General maintenance - failed light bulbs, light
movers, fans, loose ducting, leaks etc. should
be replaced or repaired. |
Weekly
|
The growing medium should be flushed once a week
to stop nutrient lock up. |
|
Complete reservoir change should done weekly to
prevent nutrient imbalances and bacteria build-up. |
|
Foliar spraying for disease and insect pests
should be done weekly to prevent outbreaks. |
End of each crop
|
The hydroponics system should be completely
sanitized at the end of each crop. This will
minimize disease carry over to the next crop. |
|
The grow room should be sanitized with
insecticides and fungicides. Walls, floors,
ceilings and equipment should be wiped down to
remove insects/eggs and fungi spores. The
cleaner the grower is in his growing room the
fewer problems he will have in the following
crop. |
What are the advantages and
disadvantages to using
hydroponics and growing indoors?
There are many advantages and
disadvantages to gardening
indoors using hydroponics. Let's
start off with some of the
advantages:
Bigger, Better, Faster
Growing hydroponically allows
for bigger, healthier plants
that usually grow faster and
produce more fruit. When growing
indoors and using the proper
lighting, most plants will go
from seed to flower in as little
as 3 months or less.
Harvest fresh fruit and
vegetables year round
Since you are growing indoors
with the aid of artificial
lighting, you can decide when to
grow. You are not dependent on
the seasons to decide when you
can plant and harvest.
Total Environmental Control
Too hot in your room – vent out
your light. Too cold - add a
heater. Too humid - bring in
some fresh air. Indoor gardening
allows you to provide optimal
conditions for your plants to
grow in. Being indoors also
helps avoid mold, pests and
other adverse creatures.
Ease and Simplicity
Hydroponics is actually derived
from Greek meaning "water" and "labor". Hydroponic systems do
all the work for you. Simply set
the timer and the system
automatically delivers water and
nutrients to the plants.
There are also a few
disadvantages to gardening
indoors:
Cost
Gardening indoors is more
expensive than traditional
gardening. The initial costs are
much more significant and
maintenance costs will also be a
factor.
Time
Hydroponic gardens will not take
up all of your time, but you
will need to pay more attention
to the system then you would to
plants growing outdoors. You
will need to check your pH
frequently, change out your
nutrients once a week and
perform general maintenance on
your garden to achieve optimal
performance.
How often should you change your
reservoir?
We recommend that you change
your reservoir once a week. This
entails "dumping" your reservoir
and re-filling it with fresh
water and nutrients. The reason
for this is that as the plants
feed, the nutrient solution will
fall out of balance. Also,
bacteria grows at a geometric
rate. If you change your
solution every week you will
decrease the possibility of
bacteria becoming a problem.
While it is possible to go
longer between changes if you
are using reverse osmosis water
instead of tap water, you still
have the bacteria issue to
contend with, so unless you are
using something to inhibit the
bacterial growth, you should
still change your reservoir
weekly.
What does an air stone do?
An air stone helps to provide
oxygenate the nutrient solution.
This oxygen is extremely
beneficial to the root zone and
helps to promote fast, healthy
growth as well as prevent
disease. This is one of the main
reasons that plants growing in a
hydroponic system grow so much
faster than plants in soil. If
you are growing in soil you can
still reap some of the rewards
of oxygen by simply oxygenating
your water before applying it to
the soil.
What size water pump do I need
for a reservoir that hold "x"
number of gallons?
The size of your pump doesn't
depend on the size of your
reservoir; rather it depends on
how far you need to pump your
water and how much water you
need to pump. You want to avoid
overworking your pump, so in
choosing the proper pump you
will want to choose one with at
least 20% more power than need.
To find out your appropriate
pump size you will need to
determine how much water is
necessary to fill your tray. If
your tray is in the shape of a
rectangle or square then you
will need to apply the following
formula to determine its volume:
Length (ft) x Width (ft) x
Average Depth (ft) x 7.5 = ? US
gallons
This will give you the total
gallons that your tray can hold.
It is a good idea to always get
a pump that is at least 20%
larger than necessary to avoid
overworking it.
After you've determined your
volume requirements you need to
find out how far "up" the water
needs to be lifted in order to
reach the tray. Simply measure
the distance between your pump
and the entry point in your
tray; most systems will have a
distance of under 3'. This
vertical distance will have an
adverse affect on the pump and
this affect must be accounted
for. In essence, the greater the
vertical distance the water must
travel, the stronger the pump
needs to be. The following chart
will show you how vertical
distance affects the pumps. Note
the loss of power of each pump
as the vertical height
increases.
|
Pump Size (GPH) |
Height Lifted |
|
|
1ft |
3ft |
5ft |
7ft |
9ft |
|
120 |
120 |
70 |
40 |
x |
x |
|
170 |
170 |
130 |
70 |
x |
x |
| 205 |
205 |
170 |
120 |
40 |
x |
| 300 |
300 |
250 |
200 |
160 |
110 |
| 500 |
500 |
350 |
280 |
200 |
150 |
| 700 |
700 |
520 |
350 |
280 |
200 |
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