Why does reactive power affect voltage?
Why does reactive power influence the voltage? Suppose you have a (weak) power system with a large reactive load. If you suddenly disconnect the load, you would experience a peak in the voltage.
First, we need to define what exactly is being asked. Now that you have stated this is regarding a utility-scale power system, not the output of a opamp or something, we know what "reactive power" means. This is a shortcut used in the electric power industry. Ideally the load on the system would be resistive, but in reality is is partially inductive. They separate this load into the pure resistive and pure inductive components and refer to what is delivered to the resistance as "real power" and what is delivered to the inductance as "reactive power".
This gives rise to some interesting things, like that a capacitor accross a transmission line is a reative power generator. Yes, that sounds funny, but if you follow the definition of reactive power above, this is all consistant and no physics is violated. In fact, capacitors are sometimes used to "generate" reactive power.
The actual current coming out of a generator is lagging the voltage by a small phase angle. Instead of thinking of this as a magnitude and phase angle, it is thought of as two separate components with separate magnitudes, one at 0 phase and the other lagging at 90° phase. The former is the current that causes real power and the latter reactive power. The two ways of describing the overall current with respect to the voltage are mathematically equivalent (each can be unambiguously converted to the other).
So the question comes down to why does generator current that is lagging the voltage by 90° cause the voltage to go down? I think there are two answers to this.
First, any current, regardless of phase, still causes a voltage drop accross the inevitable resistance in the system. This current crosses 0 at the peak of the voltage, so you might say it shouldn't effect the voltage peak. However, the current is negative right before the voltage peak. This can actually cause a little higher apparent (after the voltage drop on the series resistance) voltage peak immediately before the open-circuit voltage peak. Put another way, due to non-zero source resistance, the apparent output voltage has a different peak in a different place than the open-circuit voltage does.
I think the real answer has to do with unstated assumptions built into the question, which is a control system around the generator. What you are really seeing the reaction to by removing reactive load is not that of the bare generator, but that of the generator with its control system compensating for the change in load. Again, the inevitable resistance in the system times the reactive current causes real losses. Note that some of that "resistance" may not be direct electrical resistance, but mechanical issues projected to the electrical system. Those real losses are going to add to the real load on the generator, so removing the reactive load still relieves some real load.
This mechanism gets more substantial the wider the "system" is that is producing the reactive power. If the system includes a transmission line, then the reactive current is still causing real I2R losses in the transmission line, which cause a real load on the generator.
Consider the source impedance of the weak power system has both a resistive and reactive component (i.e. an "ideal" voltage source in series with an RL combination). Just as a resistive load will form a "voltage divider" with the source, a reactive load will do the same. By applying the standard voltage divder rules to complex impedances, the reason for the observed result (greater voltage drop with inductive loads than with purely resistive) becomes clear.
To put it another way, there are two ways to get more current out of a reactive source impedance - one is to increase the voltage drop, the second is to increase the phase shift across the inductive component. Adding a reactive load with the same "sign" of complex impedance reduces that phase shift (as the resulting AC current in the system produces a voltage at the load more in-phase with that of the "ideal" component of the source), so the voltage drop across the source impedance must increase to deliver the same load current.
The other interpretation i make of the question relates to transients, when a large current passing though an inductor (all wiring has an inductive property) is interrupted, the collapsing magnetic field induces a voltage rise in the inductor proportional to di/dt. This creates a transient peak at the load for a fraction of a cycle, however if there is significant capacitance in the system, ringing (oscillation) can occur which spreads out the transient over a few cycles. These transients make the switching of heavy inductive loads a design challenge.