Here's code making use of PIL and Scipy's cluster package.
For simplicity I've hardcoded the filename as "image.jpg". Resizing the image is for speed: if you don't mind the wait, comment out the resize call. When run on this sample image of blue peppers it usually says the dominant colour is #d8c865, which corresponds roughly to the bright yellowish area to the lower left of the two peppers. I say "usually" because the clustering algorithm used has a degree of randomness to it. There are various ways you could change this, but for your purposes it may suit well. (Check out the options on the kmeans2() variant if you need deterministic results.)
NUM_CLUSTERS = 5
print 'reading image'
im = Image.open('image.jpg')
im = im.resize((150, 150)) # optional, to reduce time
ar = scipy.misc.fromimage(im)
shape = ar.shape
ar = ar.reshape(scipy.product(shape[:2]), shape)
print 'finding clusters'
codes, dist = scipy.cluster.vq.kmeans(ar, NUM_CLUSTERS)
print 'cluster centres:\n', codes
vecs, dist = scipy.cluster.vq.vq(ar, codes) # assign codes
counts, bins = scipy.histogram(vecs, len(codes)) # count occurrences
index_max = scipy.argmax(counts) # find most frequent
peak = codes[index_max]
colour = ''.join(chr(c) for c in peak).encode('hex')
print 'most frequent is %s (#%s)' % (peak, colour)
Note: when I expand the number of clusters to find from 5 to 10 or 15, it frequently gave results that were greenish or bluish. Given the input image, those are reasonable results too... I can't tell which colour is really dominant in that image either, so I don't fault the algorithm!
Also a small bonus: save the reduced-size image with only the N most-frequent colours:
# bonus: save image using only the N most common colours
c = ar.copy()
for i, code in enumerate(codes):
c[scipy.r_[scipy.where(vecs==i)],:] = code
print 'saved clustered image'