For every abelian groups $G$ let $\mathrm{d}G$ be its maximal divisible subgroup. Then $G \mapsto G/\mathrm{d}G$ is a right exact functor $\mathbf{Ab} \to \mathbf{Ab}$.
Let $$ 0 \to G \xrightarrow{i} H \xrightarrow{p} K \to 0 $$ be an exact sequence. I'm having trouble showing for the sequence $$ G/\mathrm{d}G \xrightarrow{i'} H/\mathrm{d}H \xrightarrow{p'} K/\mathrm{d}K \to 0 $$ (where $p' \colon h + \mathrm{d}H \mapsto p(h) + \mathrm{d}K$ ) that $\ker p' \subseteq \operatorname{im} i'$.
So let $h + \mathrm{d}H \in \ker p'$. Then $p(h) \in \mathrm{d}K$. I need to show that there is $h'$ in $\mathrm{d}H$ such that $p(h) = n p(h')$ for some integer $n$ in order to draw the conclusion.
Any help would be appreciated!
Consider the short exact sequence: $$0\to\mathbb{Z}^{\mathbb{N}_{>0}}\stackrel i \to \mathbb{Z}^{\mathbb{N}_{>0}}\stackrel p\to \mathbb{Q}\to 0,$$ where $i(f_n)=(n+1)e_{n+1}-e_n$ and $p(e_n)=\frac1{n!}$ for $n\geq 1$.
Applying the functor results in the sequence: $$0\to\mathbb{Z}^{\mathbb{N}_{>0}}\stackrel i \to \mathbb{Z}^{\mathbb{N}_{>0}}\to 0\to 0,$$ which is not exact in the middle term.
Note $\mathbb{Z}^{\mathbb{N}_{>0}}$ denotes the direct sum of copies of $\mathbb{Z}$ indexed over $\mathbb{N}_{>0}$ (not the direct product).