Why do my "steel ice cubes" have water in them?

Question

I recently bought steel ice cubes. A better name is probably "steel cubes with unidentified liquid" which I presume is water. When I opened the package I was quite surprised that they contained some liquid. I thought it was going to be a solid cube of steel. This made me think how do steel cubes compare to plastic cubes filled with water (or regular ice cubes)?

Volume of cube: $V=(2\ \mathrm{cm})^3=8\cdot10^{-6}\mathrm{m^3}$
Specific heat capacity of ice $C_i=2090\left[\mathrm{\frac{J}{kg ^\circ C}}\right]$
Specific heat capacity of steel $C_s=466\left[\mathrm{\frac{J}{kg ^\circ C}}\right]$
Density of ice $\rho_i=917 \left[\mathrm{\frac{kg}{m^3}}\right]$
Density of steel $\rho_s=7750 \left[\mathrm{\frac{kg}{m^3}}\right]$

I used the lower boundary for density of steel (from source).

Ice cubes:
Heat capacity $C=\rho_i\cdot V \cdot C_i \approx 15.33\left[\mathrm{\frac{J}{^\circ C}}\right]$

Steel cubes:
Heat capacity $C=\rho_s\cdot V \cdot C_s \approx 28.89\left[\mathrm{\frac{J}{^\circ C}}\right]$

Even though I used the lower boundary for the density of steel it still has more heat capacity than ice. From this it seems to make most sense to produce cubes of solid steel since it would cool your drink more.

Why do my steel cubes (used for cooling drinks) contain (presumably) water?

Could it be that solid steel cubes transfer their heat too quickly? Hence manufacturers add water inside which does lower the heat capacity but make the cubes cool for a longer time period? Or am I interpreting the results from my calculations wrongly? Or maybe my calculations are wrong?

Sources where I get values:

https://en.wikipedia.org/wiki/Steel
https://www.cs.mcgill.ca/~rwest/wikispeedia/wpcd/wp/i/Ice.htm
https://gchem.cm.utexas.edu/data/section2.php?target=heat-capacities.php

Answer 1

Water thaws at 0°C. The latent heat of fusion of water is $L_i = 344000$ J/kg, which means that to thaw the frozen water inside your cubes requires much, much more energy than you're accounting for. Steel, on the other hand, undergoes no such phase transformation (edit: at comfortable drinking temperatures), and so it cannot invoke the magic of phase transformations to cool your drinks.

To put some numbers on it: how cold would a cube of solid steel have to be to absorb as much heat as the same volume of melting ice? We want $$ \rho_s C_s V \Delta T = \rho_i L_i V \quad \Rightarrow \Delta T = \frac{\rho_i L_i}{\rho_s C_s} = 87.3 {}^\circ \mathrm{C}. $$ So to match the performance of a melting ice cube at 0°C, your steel cube would have to start out at -87°C or so, which is clearly out of the range of household freezers.