Here is a sketch of the proof, some details filled below. All categories
are $(\infty,1)$-categories and all functors are $(\infty,1)$-functors
unless specified otherwise. The notion of a topological abelian group
can be defined within higher topos theory. The category of abelian
groups is equivalent to the category of cartesian functors from a
certain representing category $\mathrm{\mathcal{T}Ab}$ with finite
products to the topos. The 1-truncation of $\mathrm{\mathcal{T}Ab}$
is equivalent to the Lawvere theory of abelian groups, and its models
in any 1-truncated topos is the classic category of abelian groups.
The important thing here is that the free abelian groups functor is
defined naturally for any cocomplete category with finite products
as a colimit of finite powers of the generating object, thus it is
preserved by any functor which preserves colimits and finite products.
In particular, it it preserved by the $n$-truncation functor $\tau_{\leqslant n}:\mathrm{Space}\to\mathrm{Space}_{\leqslant n}$,
since $\mathrm{Space}$ is a topos (HTT, lemma 6.5.1.2, also [on
nLab][1]). Hurewicz theorem requires working not with $\mathrm{Space}$
itself, but with the category of pointed and, more generally, $k$-connected
spaces $\mathrm{Space}^{>k}$. The truncation functor on these categories
also preserves finite products and colimits. The free abelian group
functor on pointed spaces acts as $\left(X,\ast\right)\mapsto F\left(X\right)/F\left(\ast\right)$,
i.e. as reduced homology. Note that it's just a specialization of
the general definition. $F$ maps the subcategory $\mathrm{Space}^{>k}\hookrightarrow\mathrm{Space}^{>-1}$
to itself, since $\mathrm{Space^{>k}}$ is closed under finite products
and small colimits. This means that for any $\left(n-1\right)$-connected
space $X$ the canonical morphism $X\to FX$ under truncation induces
a morphism $\tau_{\leqslant n}X\to F\tau_{\leqslant n}X$, where $\tau_{\leqslant n}X$
lives in the category of $\left(n-1\right)$-connected $n$-truncated
spaces $\mathrm{Space}_{\leqslant n}^{>n-1}$ and $F$ is the free
abelian group functor for $\mathrm{Space}_{\leqslant n}^{>n-1}$.
The loop–deloop adjunction induces an equivalence between the categories
$\mathrm{Space}^{>k}$ and $E_{k+1}\mathrm{Grp}\left(\mathrm{Space}\right)$
— $E_{k+1}$-monoidal group objects in spaces, thus $\mathrm{Space}_{\leqslant n}^{>n-1}\simeq E_{n}\mathrm{Grp}\left(\mathrm{Set}\right)$.
For $n=0$ $E_{n}\mathrm{Grp}\left(\mathrm{Set}\right)\simeq\mathrm{Set}_{\bullet}$
and the Hurewicz moprhism is the inclusion of a pointed set into its
free abelian group (note that the marked point maps to $0$). For
$n=1$ $E_{n}\mathrm{Grp}\left(\mathrm{Set}\right)\simeq\mathrm{Grp}\left(\mathrm{Set}\right)$,
the abelian groups in the $1$-category of groups are just classical
abelian groups and the Hurewicz morphism is the abelianization of
the group $\pi_{1}\left(X\right)$. For $n>1$ the sequence of $E_{n}$-monoids
stabilizes, all $E_{n}\mathrm{Grp}\left(\mathrm{Set}\right)\simeq\mathrm{Ab}\left(\mathrm{Set}\right)$.
The category of abelian groups in the $1$-category of abelian groups
is the $1$-category of abelian groups itself, thus both the forgetful
functor and the free abelian group functor are identity and the Hurewicz
morphism is the identity as well, QED. 

The trickiest part of the theorem is to actually state it: we need
to define the free abelian group functor $F$ as a functor on the
category of spaces (here and below all categories are $(\infty,1)$-categories
and all functors are $(\infty,1)$-functors unless specified otherwise)
and show that it can be constructed via finite products and small
colimits. This isn't obvious since the natural homotopization of abelian
monoids is the category of $E_{\infty}$ monoids, which is the category
of algebras over the operad of abelian groups $\mathrm{Comm}$. Thus
we will proceed in several steps: first introduce the notion of $E_{\infty}$-groups
which are the same as connective spectra. The abelian groups are $H\mathbb{Z}$-modules
in the category of spectra (by Dold–Kan correspondence the category
of simplicial abelian groups is equivalent to the category of non-negative
chain complexes, which are equivalent to connective $H\mathbb{Z}$-module
spectra). Here $H\mathbb{Z}$ is an $E_{\infty}$-ring spectrum which
is the 0-truncation of the sphere spectrum. The free abelian group
functor in the category of spectra is thus $X\mapsto H\mathbb{Z}\otimes X$,
by the universality of left adjoints the free abelian group functor
in the category of spaces is $X\mapsto\Omega^{\infty}(H\mathbb{Z}\otimes\Sigma^{\infty}X_{+})$.
This is the composition of three freeness functors: the free $E_{\infty}$-monoid
one, followed by the group completion of a monoid, followed by the
free $H\mathbb{Z}$-algebra one which is the smash product of spectra.
The first two ones are of the required type (products and colimits)
as free algebra functors. The third one is also of this type since
the smash product aka $E_{\infty}$-tensor product can be represented
by the Day convolution, which involves only finite products and colimits,
of the corresponding functors on the representing Lawvere theory of
$E_{\infty}$-groups. Note that if we model this theory in $1$-categories
rather than $\infty$-categories, then the $E_{\infty}$-monoid structure
reduces to the abelian monoid one, the tensor product is just the
ordinary tensor product over $\mathbb{Z}$ and the whole composition
equals to the free abelian group functor.

Some other trivial applications of the above technique: for any abelian
group $A$ the Hurewicz morphism for $A$-homology on the lowest nontrivial
homotopy group is the composition of abelianization and the map $\pi_{n}\left(X\right)\to A\otimes\pi_{n}\left(X\right)$.
Less trivially, let us consider the free group functor, which is equivalent
to $\Omega\Sigma$. The natural transformation $X\to\Omega\Sigma X$
is described by the Freudenthal's theorem: it is $\left(2n-2\right)$-connected
if $X$ is $\left(n-1\right)$-connected. After looping and truncating
this is equivalent to the statement that on the category of $\left(n-2\right)$-truncated
$E_{n}$-groups the free group functor is an equivalence. This in
turn is equivalent to the statement that the categories of models
of $E_{n+k}$-groups in $n$-categories are equivalent for $k\geqslant1$,
which is a generalization of the claim that $E_{k}\mathrm{Grp}\left(\mathrm{Set}\right)\simeq\mathrm{Ab}$
for $k\geqslant2$ (in fact we don't need the structure of a group,
only a monoid). The structure of $E_{n+k}$-monoid is given by $\left(n+k\right)$
commuting (necessarily equal) associtive multiplications, which amounts
to giving a series of commuting $\left(n+k\right)$-dimensional cubes
which have the muplication maps on edges, the commutativity conditions
on 2-faces etc for all operation arities. The highest degree condition
corresponds to the cube itself and is $\left(n+k\right)$-dimensional.
In an $n$-category it reduces to a relation, i.e. if the corresponding
$\left(n+k\right)$-dimensional paths exists then they are unique
and no relation of higher degree between them is possible, thus any
$E_{n+1}$-monoid is automatically an $E_{n+k}$-monoid.

As usual in category theory, we have moved the burden of work from
the proof of the statement to the definitions, which reduces the actual
proof to some purely formal statements. One could probably say that
it requires a perverted state of mind to claim that the proof above
is "simple", however I still make this claim: it involves
only general facts about higher algebras and higher categories. In
a world where children study homotopy theory instead of set theory
all statements above would be most natural and can be verified mentally.

[1]: https://ncatlab.org/nlab/show/n-truncated+object+of+an+%28infinity%2C1%29-category#GeneralPropsTruncation
 "Truncation: general properties"