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Helpful Hints on the Use of a Volumetric
Pipet
by Oliver Seely
This Web page, accompanying photos and video are in the public domain and may be copied
without restriction.
The volumetric analysis exercises will make use of a 25 mL volumetric pipet. Dr. Reilly,
always willing to lend a hand, is going to be our demonstrator on the proper use of a volumetric
pipet. Our pipets are kept in the drawers at the west end of lab. Pick out a 25 mL pipet and
practice a few times with distilled water before using it to draw in any reagent.
It is always a good idea to examine each pipet you take from the drawer because occasionally you
will find a stowaway who got in and couldn't get out. Here's one that got stuck a long time ago,
maybe even before Proposition 13. We wouldn't know how old he is without first doing some
C-14 dating on him (far right). You ought also to examine the tip for breakage. Many breaks are
trivial. That is they show minor chipping around the edge of the tip, but here's one (near right) in
which the entire wall has fractured at one point. You can just barely see the intact nozzle, but the
pipet is unusable because the liquid path has been compromised. Better discard this one.
You're going to use one of two kinds of suction devices to fill the pipet. If your suction device is
a rubber bulb, it ought NOT to be placed so that it is attached to the mouth of the pipet.
It ought instead to be pressed so that the hole of the bulb makes an air-tight seal against the
mouth of the pipet. Note here that Dr. Reilly has squeezed the bulb before he pressed it against
the mouth of the pipet. The tip of the pipet can then be placed in the solution which is to be
drawn up and the bulb slowly released. This method requires a little practice but in the final
analysis may be considerably more practical and satisfying than the use of the high-tech bulb Dr.
Reilly will show you next.
You must exercise care not to allow the tip of the pipet to break the surface of the liquid while
you are drawing in the solution or the sudden decrease in viscosity at the tip will cause a large
amount of liquid to contaminate the inside of your rubber bulb because of the entry of air pushing
the liquid up beyond the mouth of the pipet. Draw up the solution until the meniscus is several
centimeters above the calibration line, then quickly put your finger over the open hole of the pipet.
Making sure that your line of sight is perpendicular to the length of the pipet, allow a tiny amount
of air in so that the meniscus drops to the calibration mark, as Dr. Reilly is showing at the right.
When the bottom of the meniscus coincides with the calibration mark, your pipet contains a
precisely measured volume, as in the image at the left.
The pipet can then be removed from your reagent solution, transferred to the receiving flask and
allowed to drain.
A volumetric pipet should not be "blown out" to eject all liquid at the tip because volumetric
pipets are calibrated in a manner that takes into account the solution which remains at the tip due
to surface tension.
The "high-tech"pipet bulb is an Eppendorf bulb. It can be placed firmly on the mouth of the pipet.
At the side of the Eppendorf is a protruding lever attached to a slide. Pull it down to create a
vacuum inside the bulb.
Use your thumb to push the two way valve up when you are ready to draw your solution into the
pipet, as shown at the left, but make sure the nozzle of your pipet remains
below the surface of the solution (right) so that you don't suck air into your pipet causing lots of
solution to pass into the filter in the bulb area which will require disassembly, drying out and
replacement of parts.
When a sufficient amount of the solution has been drawn in so that the meniscus is above the
calibration mark, use your
thumb to slide the two-way valve down, as shown at the left. Do it gently so that the meniscus
drops slowly to the calibration mark. Then you can transfer the solution in the pipet to the
receiving flask and push the two-way valve lever down to empty the pipet. The nozzle of the
pipet can be kept in the open air for the transfer, as shown at the right.
Finally, pipettes and burettes accumulate inert solid material which must be removed from time to
time. Here at the left is the nozzle of a burette which has material which will not pass through.
You may have to use a wire, available on the lower ledge of the burette case, to clean out this
material. It is best to do it with the petcock valve removed so that when you do a reverse wash
after poking it free, the material can be washed out at the point of the valve instead of at the other
end of the burette cylinder.
To illustrate that sometimes things just don't work out as we wish, look at the piece of solid
material lodged in the nozzle of the pipette on the left. Usually, poking the material with a piece
of wire breaks it up so that it flows freely out the nozzle, but in this case the material won't be
broken (right photo).
Water from a wash bottle was squirted in the upper neck of the pipette to wash the material out
through the nozzle, but it wouldn't budge. The only solution here is to do a normal filling of the
pipette with distilled water and then a reverse drain through the upper neck so as to wash the
particle out the other end.
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Oliver's index of chemical demonstrations