The HMF – What’s That?
Rüdiger
Rautenberg on a cheap filtration method deserving of greater
exposure…
A
planted aquarium set up with a Hamburger Matten Filter. © Rüdiger
Rautenberg
The HMF (Hamburger Matten Filter) is apparently
not all that well known outside mainland Europe, or so I’ve been
told. I cannot speak for the whole of Europe but in Germany it is
certainly a widespread and well-loved method of filtering fish tanks
and is favored especially by breeders and hobbyists who maintain a
larger number of tanks in a dedicated fish room.
This
article will only briefly touch on exactly how the filter works since
that is a rather complex subject and has a lot to do with the very
basics of filtration in a fish tank. There could be a separate
article on that if enough people are interested. Here we concentrate
on the general set-up of the HMF, its main advantages and how to
build one.
The
history of the HMF is somewhat shrouded. Its origins are assumed to
lie in the former DDR (East Germany) but there’s no confirmation of
that as yet. And strictly speaking, the HMF is not really an
invention but rather a further development and improvement of the
well-known sponge or bubble filter.
Regular
sponge filters have a distinct disadvantage in that they are only
suitable for smaller tanks. If you wanted to run them in anything
larger than a standard 54 l, you’d need a whole array of them,
which takes up space and is rather unsightly.
The
medium of the HMF is composed of sponge sheets (‘Matten’), which
should be available at either your LFS or a specialist shop for fish
ponds. I have seen them in the pond section of the larger hardware
stores too. The size of the pre-cut sheets usually starts at 50 x 50
cm and can go up to 100 x 200 cm.
Filter
sponge of grade 30 ppi. © Rüdiger Rautenberg
Different
grades are available but for our purpose only two are really
relevant. I recommend 30 ppi (pores per inch) for the general show
tank and 40 ppi for a breeding tank. Anything below 30 ppi loses its
mechanical filtration properties to a certain degree, resulting in
suspended solids in the water column. Anything above 40 ppi
clogs a lot faster and thus requires more maintenance.
It
comes in 10, 20, 30, 40 and 50 mm thickness of which I exclusively
use the 50 mm variant. Additionally the sponge comes in two colors,
black and blue, of which I personally prefer the black since it is
less conspicuous in the tank (unless of course you have a blue
background). But it is (for some unknown reason) more expensive than
the blue variety.
Filter
sponge of grade 40 ppi. © Rüdiger Rautenberg
The
HMF started out as a simple separation of the tank (front to back and
top to bottom) by means of a sponge sheet, driven by an uplift tube
plus diaphragm pump. The space behind the sponge needs to be just big
enough to accommodate either the uplift tube or motorised pump
depending on your preferences.
I
personally use motor pumps simply because I just cannot stand the
noise of a diaphragm pump, which is needed to operate the uplift.
Additionally, with the motorised pump, I know the exact capacity,
i.e., how much water is moved per hour. So all four examples
introduced here are based on motorised pumps as a means to transport
the water.
The
water is pumped from the small compartment behind the sponge back
into the main part of the tank. From there the water has to pass
through the sponge into the pump compartment, i.e., the “filter
chamber”.
The
mechanical filter capacity of the sponge has already been mentioned
but much more importantly, it is chemically inert and offers a huge
surface area for beneficial bacteria to colonise and hence it is
chiefly a biological filter (suggested further reading for those
unfamiliar with biological filtration: search the web for “Nitrogen
cycle” or read the article “Cycling
an Aquarium”
on these pages.)
This
basic design has two tiny disadvantages I don’t like, however.
1.
when the foam starts clogging with usage (which is inevitable), it
will bend towards the suction of the pump and allow unfiltered water
to flow past the edges.
2.
the filter surface area the water flows through is a given due to the
tank dimensions, and one has to adjust the capacity of the pump to
allow for effective biological filtration (see formula later in this
article).
For
these reasons I prefer the “HMEF”
(Hamburger Matten Eck Filter), which is nothing but a “corner
variant” of the HMF. Due to the arch of the sponge it cannot be
sucked inwards (given the right thickness) thus it holds its shape.
To
set this up I use two lengths of angled PVC, siliconing these to the
glass (please be sure to ONLY use
aquarium safe silicone) and add a strip of polypropylene (PP) or
similar at the bottom. This strip serves to prevent gravel or other
substrate from entering the “filter chamber” when I need to
remove the sponge for cleaning:
Basic
framework of a corner HMEF, siliconed in place. © Rüdiger
Rautenberg
©
Rüdiger Rautenberg
Then I slide in the sponge:
©
Rüdiger Rautenberg
In this case I decided to position the filter
outlet at about the 1/3 of tank height. This is not important for the
efficacy of the filter, only in terms of the desired water flow in
the tank:
©
Rüdiger Rautenberg
Because the water level was intended to be at
the top of the tank, I closed the opening with a piece of sponge to
prevent fish from entering. Since it was an open tank I added some
hydrocultured plants to make the whole thing a bit prettier (the
heater was later moved into the “filter chamber” thus becoming
invisible):
©
Rüdiger Rautenberg
The frontal shot of the tank was taken less
than 30 minutes after setting it up. As you see, the filter has
already cleared the water almost entirely. But what you see too is
that the filter isn’t an eyesore at all. It will be even less so
once the plants have grown a bit:
©
Rüdiger Rautenberg
So,
how big must the filter be, and how do we decide the dimensions?
That
depends on a number of factors including:
1.
Water turnover per hour
2.
Flow-rate
3.
Volume of the tank
To
achieve effective biological filtration the following parameters have
proven themselves as most efficient.
-
The water turnover should be between 2 and 3 times the tank volume
per hour.
-
The flow-rate should be between 5 and 10 cm per minute.
The
maths
For
our example let’s take a standard 160 l tank (100 x 40 x 40 cm) and
as the golden medium a turnover of 2.5 x volume/hour and flow-rate of
7.5 cm/minute. We have a 160 l tank and 400 l/h pump, but
how do we achieve the correct flow-rate?
Flow-rate
refers to how much water flows through a filter sponge of given
surface area (taken as a cross-section, i.e., sponge depth x sponge
height) within a certain amount of time. There is of course a formula
for this:
Cross-section
[A] = Volume [Q] x Water turnover [n] x 1000 / (Flow rate [V] x 60)
in
our example:
A
= 160 x 2.5 x 1000 / 7.5 x 60 = 400 000 / 450 = 888.88 cm² ≈ 890
cm²
Since
the height of the tank is a fixed we simply divide this result by 40
(tank height in cm) to calculate the width of the piece of sponge we
need, i.e., 890 cm² / 40 cm = 22.25 cm, ≈ 22.5 cm. Therefore
we cut out a piece of sponge measuring 40 x 22.5 cm.
The
only thing left now is to calculate where we have to silicone the PVC
angle to the glass to achieve a nicely-shaped filter which is
basically a quarter of a circle.
The
circumference of a circle = π (pi)
x diameter or π x 2 x radius. In this case we can easily calculate
the circumference by multiplying the width of our filter material by
four (4 x 22.25 = 89 cm) but now require the radius as this
corresponds to how far away from the tank corner we should position
our PVC angles. This is calculated as follows:
r
= c / 2 x π = 89 / 2 x π = 14.167899, ≈ 14.5 cm.
In
the tank we now measure 14.5 cm from each side of the corner where
the filter is supposed to go and mark where to place the PVC angles
at both the top and bottom. The rest is a piece of cake.
In
summary…
I
hope I could bring across how easy it is to build a really effective,
low cost and low maintenance filter. The advantages of the HMF can be
quickly summarised:
-
Its
biological efficacy is rivaled only by more expensive, much larger
and more difficult to build filters such as fluidised beds or wet
and dry trickle filters.
-
It
is dirt cheap to build and operate – you don’t have to buy new
filter material for years after.
-
Very
low maintenance – the one pictured above ran for more than a year
with no maintenance at all before I had to clean it.
-
When
it becomes necessary to clean it, it takes about 15 minutes if that.
-
Additional
equipment, e.g., heater, CO2 diffuser, etc., can be placed (hidden)
in the “filter chamber”.
After
some years of experience with the HMF, it was, is and will stay my
first choice of filtration for freshwater as well as brackish
aquaria.
To
round off this article, I’d like to show a few more examples of
HMFs that I build for different purposes.
First
the one I built for my 160 cm long “Asian river”. You can
see that the basic set-up is the same as in the one above except for
a hole at the bottom.
©
Rüdiger Rautenberg
As an outlet I built a modified “river
manifold”:
©
Rüdiger Rautenberg
Again you can see that the filter fits into the
tank quite nicely without being too conspicuous. The picture was
taken about 15 minutes after the tank was completely filled.
©
Rüdiger Rautenberg
Next is a “mobile” HMF fitted with a
spraybar I built for a 54 l dwarf puffer tank:
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
And finally another mobile solution that was
designed for my ≈ 30 l special-purpose “buckets”:
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
N.B. The
outflows in all 4 models cannot be driven by uplift tubes since the
latter do not produce sufficient water pressure, and the outlet
should be just above the water surface (yet another reason I prefer
the motor pump).
Filter
foam is best cut with a run off the mill Stanley knife (broad blade)
with new blades. Use a guide, like an aluminium angle or ruler, but
don’t press down, just gently hold it in place so it can’t move.
Don’t exert much pressure on the knife, just gently slide it
through the material and cut in 2 or 3 passes.
For
those who understand a bit of the German language I recommend the
following web site for further reading: www.deters-ing.de
Olaf
Deters is one of the guys who spent a lot of energy improving on the
original HMF design. He’s a well known aquarist, specialising in
killifish, and you can read his article in the German-language
version of the magazine Amazonas number 44 Nov / Dec 2012 pp. 28 –
39.
Concluding
I would like to emphasise that I by no means have “invented” nor
have been involved in the “invention” of the HMF or any part
thereof. I have though, where necessary, modified it to my and,
more importantly, my fishes’ needs.
A
planted aquarium set up with a Hamburger Matten Filter. © Rüdiger
Rautenberg
Filter
sponge of grade 30 ppi. © Rüdiger Rautenberg
Filter
sponge of grade 40 ppi. © Rüdiger Rautenberg
Basic
framework of a corner HMEF, siliconed in place. © Rüdiger
Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
Its
biological efficacy is rivaled only by more expensive, much larger
and more difficult to build filters such as fluidised beds or wet
and dry trickle filters.
It
is dirt cheap to build and operate – you don’t have to buy new
filter material for years after.
Very
low maintenance – the one pictured above ran for more than a year
with no maintenance at all before I had to clean it.
When
it becomes necessary to clean it, it takes about 15 minutes if that.
Additional
equipment, e.g., heater, CO2 diffuser, etc., can be placed (hidden)
in the “filter chamber”.
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
©
Rüdiger Rautenberg
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