Lemma 1. If $A$ is an abelian group, $a,b\in A$, then the order of $ab$ divides the least common multiple of the orders of $a$ and of $b$.
Proof. Let $m$ be the least common multiple of the orders of $a$ and $b$. Then $a^m = b^m = 1$ (since $m$ is a multiple of the order), so $(ab)^m = a^mb^m = 1$. Thus, the order of $ab$ divides $m$. $\Box$
Lemma 2. If $A$ is an abelian group, $a,b\in A$, and $\langle a\rangle\cap\langle b\rangle = \{1\}$, then the order of $ab$ is equal to the least common multiple of the orders of $a$ and of $b$.
Proof. Let $k$ be an integer such that of $(ab)^k=1$. Then $(ab)^k = a^kb^k = 1$, hence $a^k = b^{-k}$. Therefore, $a^k,b^{-k}\in\langle a\rangle\cap\langle b\rangle =\{1\}$. So the order of $a$ divides $k$, and the order of $b$ divides $k$; thus, the lcm of the orders divides $k$. In particular, the lcm of the orders divides the order of $ab$, and by Lemma 2, the order of $ab$ divides the lcm. Thus, the order of $ab$ equals the lcm of the orders. $\Box$
Lemma 3. If $A$ is an abelian group, and $a$ and $b$ have relatively prime orders, then $\langle a\rangle\cap\langle b\rangle = \{1\}$.
Proof. If $x\in \langle a\rangle\cap\langle b\rangle$, then $x=a^i = b^j$ for some $i$ and $j$. Thus, the order of $x$ divides the order of $a$ and the order of $b$, hence it divides the gcd of the order; but since the orders are relatively prime, the gcd is $1$. Thus, $x$ is of order $1$, hence $x=1$. $\Box$