Well my question is as clear as its title suggests. So here I would like to clarify on the fact that an object $A^\cdot$ in $\mathrm{Ch}^{\geq 0}(\mathcal{A})$ is injective if and only if $0\longrightarrow\mathrm{H}^0(A^\cdot)\longrightarrow A^0\longrightarrow A^1\longrightarrow\cdot\cdot\cdot$ is exact and $\mathrm{H}^0(A^\cdot)$ and all $A^n$'s are injectives in $\mathcal{A}$.
Many thanks in advance!
If $X^{\bullet}$ is an object of $\mathrm{Ch}^{\geq0}(\mathcal{A})$ and for each $i\geq0$ $X^i\to I^i$ is an embedding into an injective, then $X^{\bullet}$ embeds in $$I^{\bullet}:=\dots\to 0\to I^0\oplus I^1\to I^1\oplus I^2\to I^2\oplus I^3\to\dots$$ (with the obvious maps as differentials). $I^{\bullet}$ is the product (and coproduct) of cochain complexes $J_0^{\bullet}:=\dots0\to I^0\to0\to\dots$ and $J_i^{\bullet}:=\dots0\to I^i\to I^i\to0\to\dots$ for $i>0$. Since products of injective objects are injective, it suffices to prove that $J_i^{\bullet}$ is injective for all $i\geq0$, which is straightforward since for any object $Y^{\bullet}$ of $\mathrm{Ch}^{\geq0}(\mathcal{A})$, $\operatorname{Hom}(Y^{\bullet},J_i^{\bullet})=\operatorname{Hom}_{\mathcal{A}}(Y^i,I^i)$.
