I don't know the answer to this, it seems non-trivial to me. Here are a few thoughts.

The sum consists of a variable number of summands, say s_{0} + s_{1} + ... s_{k}, where s_{i} is an integer in the interval [2, 1000]. Now each s_{i} has a prime-power factorization s_{i}=(p_{1}^{e1})*(p_{2}^{e2}) ... where e_{i} ≥ 1.

The condition that "that any two numbers from the subset don't share common prime factors" is equivalent to stating that s_{i} are pairwise relatively prime, i.e. gcd(s_{i}, s_{j})=1 for i ≠ j. Also equivalently, whenever one summand s_{i} contains a prime p that means that no other summand may contain that prime.

So how do you arrange the primes into summands? One simple rule is immediately obvious. All the primes in [500, 1000] can only appear in the sum alone as individual summands. If they are multiplied by anything else, even the smallest prime 2, the product will be too large. So that leaves the task of arranging the smaller primes. And I don't know they best way to do that. For the sake of completeness I'll provide the following short python program that shows one way.

```
def sieve_prime_set(n):
# sieve[i] = set(p1, p2, ...pn) for each prime p_i that divides i.
sieve = [set() for i in range(n + 1)]
primes = []
next_prime = 1
while True:
# find the next prime
for i in range(next_prime + 1, len(sieve)):
if not sieve[i]:
next_prime = i
break
else:
break
primes.append(next_prime)
# sieve out by this prime
for kp in range(next_prime, n + 1, next_prime):
sieve[kp].add(next_prime)
return sieve, primes
def max_sum_strategy1(sieve):
last = len(sieve) - 1
summands = [last]
max_sum = last
prime_set = sieve[last]
while last >= 2:
last -= 1
if not sieve[last] & prime_set:
max_sum += last
prime_set |= sieve[last]
summands.append(last)
return max_sum, summands, prime_set
def max_sum_strategy2(primes, n):
return sum(p ** int(log(n, p)) for p in primes)
if __name__ == '__main__':
sieve, primes = sieve_prime_set(1000)
max_sum, _, _ = max_sum_strategy1(sieve)
print(max_sum)
print(max_sum_strategy2(primes, 1000))
```

Output is

```
84972
81447
```

showing that "strategy 1" is superior.

Superior, but not necessarily optimal. For example, including 1000 seems good, but it forces us to exclude every other even summand and every summand divisible by 5. If we leave 1000 out but include 998 instead, we get to use another summand that includes 5 in it's prime factorization. But including 998 forces other summands to be excluded. So maximizing the sum is not trivial.

`sqrt(1000)`

to`1000`

, and then compare only the ones that aren't in that set. – Shinra tensei Nov 17 '17 at 10:44