D is a spherical segment, obtained by intersecting a sphere (with center the origin and radius R) with plans z=0, $z=h
PS. I believe that $\theta \in (0,2\pi)$, $\rho \in (0,R)$, $\phi \in (0,\arcsin(\frac h R))$
D is a spherical segment, obtained by intersecting a sphere (with center the origin and radius R) with plans z=0, $z=h
PS. I believe that $\theta \in (0,2\pi)$, $\rho \in (0,R)$, $\phi \in (0,\arcsin(\frac h R))$
I do assume there are two parallel planes intersecting your ball, at height $h_1< h_2$, like in your picture, and a ball centered at the origin with radius $R$. Things are a bit simpler if $h_1=0$
In cylindrical coordinates $(r,\theta,z)$ (with $\theta$ describing a circle in the $(x,y)$ plane) the set you are looking at can be described as $ \{ x = (r,\theta,z): \theta \in [-\pi,\pi), z\in [h_1,h_2], 0 \le r \le \sqrt{R^2-z^2 }\} $
Depending on whether the planes are to be considered parts of your set you may want to replace the closed interval for the $z$ coordinate by an open interval.
In spherical coordinates, $\theta \in [-\pi,\pi) $ as before, and all these $\theta$ have to be taken into account. I'll assume that $\phi\in (-\pi,\pi)$ where $\pm \pi $ correspond to north and south pole respectively. With this convention you'll need to consider $\phi$ in the range $\arcsin(h_1/R)\le \phi\le \pi$ but have to distinguish between the cases $\phi\le \arcsin(h_2/R)$ and $\phi\ge \arcsin(h_2/R)$ In the first case you'll have, for given $\phi$, $R\ge \rho \ge\rho_1 =\frac{ h_1}{\sin(\phi)} $
(that is the part of a ray from the origin with angle $\phi$ relative to the $(x,y)$ plane from the plane $z=h_1$ to the boundary of the ball) whereas in the second case you'll have
$ \frac{ h_2}{\sin(\phi)}= \rho_2\ge \rho \ge \rho_1 =\frac{ h_1}{\sin(\phi)}$
which is the part of a ray with angle $\phi$ relative to the $(x,y)$ plane between $h_1 \le z \le h_2$