You can solve your problem by dividing it into two parts:

Factorize your number into primes using any of the standard techniques. For a number of only a few million, trial division would be perfectly fine.

Take the logarithm of each factor, and pack them into bins of size log *N*.

Now, bin packing is NP-hard but in practice it is possible to find good approximate solutions using simple techniques: the first-fit algorithm packs no more than 11/9 times the optimal number of bins (plus one bin).

Here's an implementation in Python:

```
from math import exp, log, sqrt
import operator
def factorize(n):
"""
Factorize n by trial division and yield the prime factors.
>>> list(factorize(24))
[2, 2, 2, 3]
>>> list(factorize(91))
[7, 13]
>>> list(factorize(999983))
[999983]
"""
for p in xrange(2, int(sqrt(n)) + 1):
while n % p == 0:
yield p
n //= p
if n == 1:
return
yield n
def product(s):
"""
Return the product of the items in the sequence `s`.
>>> from math import factorial
>>> product(xrange(1,10)) == factorial(9)
True
"""
return reduce(operator.mul, s, 1)
def pack(objects, bin_size, cost=sum):
"""
Pack the numbers in `objects` into a small number of bins of size
`bin_size` using the first-fit decreasing algorithm. The optional
argument `cost` is a function that computes the cost of a bin.
>>> pack([2, 5, 4, 7, 1, 3, 8], 10)
[[8, 2], [7, 3], [5, 4, 1]]
>>> len(pack([6,6,5,5,5,4,4,4,4,2,2,2,2,3,3,7,7,5,5,8,8,4,4,5], 10))
11
"""
bins = []
for o in sorted(objects, reverse=True):
if o > bin_size:
raise ValueError("Object {0} is bigger than bin {1}"
.format(o, bin_size))
for b in bins:
new_cost = cost([b[0], o])
if new_cost <= bin_size:
b[0] = new_cost
b[1].append(o)
break
else:
b = [o]
bins.append([cost(b), b])
return [b[1] for b in bins]
def small_factorization(n, m):
"""
Factorize `n` into a small number of factors, subject to the
constraint that each factor is less than or equal to `m`.
>>> small_factorization(2400, 40)
[25, 24, 4]
>>> small_factorization(2400, 50)
[50, 48]
"""
return [product(b) for b in pack(factorize(n), m, cost=product)]
```

has nofactors not less than N. – harold Sep 14 '12 at 13:23