Potential energy function for high energy continuum?

For the hydrogen atom the quantised energy levels are:

$$E_n = frac{- 13.6 eV}{n^2}quadtext{with}quad n = 1,2,3…$$

One peculiar property of this quantisation is that for large $n$ the energy levels are ever closer together and for $E geq 0$ (that is $n = infty$) the energy spectrum becomes a continuum. The electron is then free, of course.

For the hydrogen atom the Potential Energy function is:

$$V(r) = frac{ – e^2}{4 pi epsilon_0 r}$$

Obviously for $r = 0, V = – infty$, for $r = infty, V = 0$

Suppose that for a quantum system we construct a Potential Energy of the general form:

$$V(r) = – frac{V_0}{f(r)},$$

with $f(r)$ a symmetric function of $r$ with a root at $r = 0$ (so that $V(0) = – infty$).

Lets also assume that $frac{1}{f(r)}$ tends to $0$ for $r = infty$ (so that $V(infty) = 0$).

Intuitively I feel that with such a Potential Energy function, the quantised energy would also smoothly convert to a continuum for high quantum numbers, going fully continuous at $E geq 0$.

My question is, can this be demonstrated or even proved (or disproved, of course)?