Oh my fault. I thought you are from the US and did not look at your profile closely.
Your plugs use 240V, 50 Hz and are usually fused to 13 Amps (G-type plugs).
Here, they are now 230V, 50 Hz and maximal 16 Amps (F or "Schuko"-plugs).
A couple of electrical safety comments here. It is current and time that are the critical parameters to consider when determining electric shock risk. The electron flow associated with current in the vicinity of the heart has the potential to disrupt the electrical signals that control the heart muscles (this how a defibrillator works). The risk to the heart is proportional to both the current and the time that current is flowing for. Additionally, current and time determine the energy dissipated in the body and hence the risk of burns. However, the current in the body is generally proportional to an externally applied voltage (called touch potential), in accordance with Ohms Law. So, the higher the voltage, the higher the current.
Attached is a chart from one of our standards that shows how long a standard human can remain in contact with an externally applied voltage and reasonably expect to survive. This chart is only valid for low voltages (up to 415V).
The reason static electricity is not deadly is two fold. A static discharge will result in a direct current and muscles are less sensitive to this compared to mains frequency alternating current. Secondly, the total energy, and hence the amount of time the current can flow for is generally very low. So a 3000V static discharge generally will not be deadly because the source will fully discharge before the current has enough time to kill you.
Electronic equipment often contains capacitors that can store significant amounts of energy (enough to kill or damage you), power supplies in particular. These can take a long time to discharge if not discharged manually. Generally (depending on the equipment) they will be discharged if you turn the equipment "on" after it is disconnected from the mains but this doesn't always work. I once received a nasty shock from the capacitors in a TV set I was working on. I had the equipment switch "on" to discharge the capacitors but they did not discharge because of one of the faults in the set. Not fun. Much better to check with a multi-meter rather than assuming.
Another important point: In Australia (and Europe AFAIK) the electrical safety standards do not require you protect against direct contact with mains voltage. When doing our protection calculations, we will not consider that you will be connected to mains voltage directly but rather through the earthed housing of some faulty piece of equipment. This means that the touch potential will be not be full mains voltage, it will be reduced by the impedance in the cables supplying the fault and the return earth path, and the target disconnection time for the protection (fuses, circuit breakers, etc) will be increased accordingly. So, don't EVER work inside a live piece of equipment unless you are trained to do so and have the proper protection (both circuit protection and personal protective equipment as appropriate).
I will not exclude it, but 3000V is the conservative number I know.
You can get up to 5MV with a good Van der Graff generator
EDIT: I forgot to add, a 16A fuse will not limit the current to 16A, nor will it blow as soon as it exceeds 16A. I've attached a time-current curve for a fairly typical 16A HRC type fuse.