The answer is **Yes**. We denote $K(G)=G({\mathbb Q})_+/\rho G^{\rm sc}({\mathbb Q})$.
We compute $K(G)$; see the corollary below.
It is clear from the corollary that $K(G)$ is canonically isomorphic to $K(H)$.

We will use Section 3 of   [M. Borovoi, Abelian Galois cohomology of reductive groups. Memoirs of the AMS 132 (1998), No. 626](https://www.tau.ac.il/~borovoi/papers/galofile.pdf),
although  all necessary results can be found in Deligne's paper
*Variétés de Shimura: interprétation modulaire, et techniques de construction de modèles canoniques,*
Proc. Sympos. Pure Math. 33, Part 2, pp. 247–289.

We consider the *crossed module* $(G^{\rm sc}\to G)$ and the *hypercohomology*
$$H^0_{\rm ab}({\mathbb Q},G):=H^0({\mathbb Q},G^{\rm sc}\to G),$$
where $G$ is in degree 0;
see the Memoir. By definition $H^0_{\rm ab}({\mathbb Q},G)$ is a group.
We consider the abelian crossed module $(Z^{\rm sc}\to Z)$, where $Z=Z(G)$ and 
 $Z^{\rm sc}=Z(G^{\rm sc})$.
The morphism of crossed modules
$$(Z^{\rm sc}\to Z)\,\longrightarrow\,(G^{\rm sc}\to G)$$
is a *quasi-isomorphism*, and hence it induces a bijection on hypercohomology,
permitting us to identify $H^0_{\rm ab}({\mathbb Q},G)$ with the abelian group $H^0({\mathbb Q},Z^{\rm sc}\to Z)$.
We conclude that $H^0_{\rm ab}({\mathbb Q},G)$ is naturally an abelian group and that it does not change under inner twisting of $G$.

The short exact sequence
$$1\to(1\to G)\to (G^{\rm sc}\to G)\to (G^{\rm sc}\to 1)\to 1$$
(where $G^{\rm sc}\to 1$ is not a crossed module) induces a hypercohomology exact sequence
$$ G^{\rm sc}({\mathbb Q})\to G({\mathbb Q})\to H^0_{\rm ab}({\mathbb Q},G)\to H^1({\mathbb Q},G^{\rm sc}),$$
where 
$${\rm ab}^0\colon G({\mathbb Q})\to H^0_{\rm ab}({\mathbb Q},G)$$
 is the *abelianization map*.
This permits us to identify  $G({\mathbb Q})/\rho G^{\rm sc}({\mathbb Q})$ with the kernel
$${\rm ker}[H^0_{\rm ab}({\mathbb Q},G)\to H^1({\mathbb Q},G^{\rm sc})]$$
(yes, this kernel is a subgroup of the abelian group $H^0_{\rm ab}({\mathbb Q},G)$ ).
This kernel might change under inner twisting of $G$, because $H^1({\mathbb Q},G^{\rm sc})$ changes under inner twisting.

By definition, 
$G({\mathbb R})_+=Z({\mathbb R})\cdot\rho G^{\rm sc}({\mathbb R})$, and hence
$$G({\mathbb R})_+/\rho G^{\rm sc}({\mathbb R})={\rm ab}^0(Z({\mathbb R}))\subset
{\rm ker}[ H^0_{\rm ab}({\mathbb R},G)\to H^1({\mathbb R}, G^{\rm sc})].$$
We see that $K(G):=G({\mathbb Q})_+/\rho G^{\rm sc}({\mathbb Q})$ can be identified with  the preimage of ${\rm ab}^0(Z({\mathbb R}))\subset H^0_{\rm ab}({\mathbb R},G)$ in ${\rm ker}[H^0_{\rm ab}({\mathbb Q},G)\to H^1({\mathbb Q},G^{\rm sc})]$.

> **Lemma.** The preimage of ${\rm ab}^0(Z({\mathbb R}))\subset H^0_{\rm ab}({\mathbb R},G)$ in ${\rm ker}[H^0_{\rm ab}({\mathbb Q},G)\to H^1({\mathbb Q},G^{\rm sc})]$
coincides with the preimage of ${\rm ab}^0(Z({\mathbb R}))$ in $H^0_{\rm ab}({\mathbb Q},G)$.

*Proof.*
Let $\xi\in H^0_{\rm ab}({\mathbb Q},G)$ lie in the preimage of
$${\rm ab}^0(Z({\mathbb R}))\subset
{\rm ker}[ H^0_{\rm ab}({\mathbb R},G) \to H^1({\mathbb R}, G^{\rm sc})].$$
Then the image of $\xi$ in $H^1({\mathbb R},G^{\rm sc})$ is trivial, and therefore,
the image of $\xi$ in $H^1({\mathbb Q},G^{\rm sc})$ lies in the kernel of the localization map
$$ H^1({\mathbb Q}, G^{\rm sc})\to H^1({\mathbb R},G^{\rm sc}).$$
By the Hasse principle for simply connected groups, this kernel is trivial.
Thus the image of  $\xi$ in $H^1({\mathbb Q},G^{\rm sc})$ is trivial, and hence $\xi$ lies in  the preimage of ${\rm ab}^0(Z({\mathbb R}))$ in ${\rm ker}[H^0_{\rm ab}({\mathbb Q},G)\to H^1({\mathbb Q},G^{\rm sc})]$, as required.

> **Corollary.** *The abelianization map ${\rm ab}^0\colon G({\mathbb Q})\to H^0_{\rm ab}({\mathbb Q},G)$ with kernel $\rho G^{\rm sc}({\mathbb Q})$ induces a canonical isomorphism between the abelian groups $K(G):=G({\mathbb Q})_+/\rho G^{\rm sc}({\mathbb Q})$
and the preimage  of ${\rm ab}^0(Z({\mathbb R}))\subset H^0_{\rm ab}({\mathbb R},G)$ in $H^0_{\rm ab}({\mathbb Q},G)$.*