OK, here's a pretty simple idea (and basically, what you're looking to do is generate a set of features, then identify if the current session behaviour is different to the previously observed behaviour). I like to think of these one-class problems (only normal behaviour to train on, want to detect significant departure) as density estimation problems, so here's a simple probability model which will allow you to get the probability of a current request pattern. Basically, when this gets too low (and how low that is will be something you need to tune for the desired behaviour), something is going on.
Our observations consist of counts for each of the pages. Let their sum, the total number of requests, be equal to c_total, and counts for each page i be p_i. Then I'd propose:
c_total ~ Poisson(\lambda)
p|c_total ~ Multinomial(\theta, c_total)
This allows you to assign probability to a new observation given learned user-specific parameters \lambda (uni-variate) and \theta (vector of same dimension as p). To do this, calculate the probability of seeing that many requests from the pmf of the Poisson distribution, then calculate the probability of seeing the page counts from the multinomial, and multiply them together. You probably then want to normalise by c_total so that you can compare sessions with different numbers of requests (since the more requests, the more numbers < 1 you're multiplying together).
So, all that's left is to get the parameters from previous, "good" sessions from that user. The simplest thing is maximum likelihood, where \lambda is the mean total number of requests in previous sessions, and \theta_i is the proportion of all page views which were p_i (for that particular user). This may work for you: however, given that you want to be learning from very small numbers of observations, I'd be tempted to go with a full Bayesian model. This will also let you neatly update parameters after each non-suspicious observation. Inference in these distributions is very easy, with conjugate priors for \lambda and \theta and analytic predictive distributions, so it won't be difficult if you're familiar with these kinds of model at all.