Porous adsorbents with hierarchical structured macropores ranging from 1 to 100 μm are prepared using a combination of freeze casting and additional sacrificial templating of polyurethane foams, with a zeolite 13X powder serving as adsorbent. The pore system of the prepared monoliths features micropores assigned to the zeolite 13X particle framework, interparticular pores of ∼1-2 μm, lamellar pores derived from freeze casting of ∼10 μm, and an interconnected pore network obtained from the sacrificial templates ranging from around 100 to 200 μm with a total porosity of 71%. Gas permeation measurements show an increase in intrinsic permeability by a factor of 14 for monoliths prepared with an additional sacrificial templated foam compared to monoliths solely providing freeze casting pores. Cyclic CO2 adsorption and desorption tests where pressure swings between 8 and 140 kPa reveal constant working capacities over multiple cycles. Furthermore, the monoliths feature a high volumetric working capacity of ∼1.34 mmol/cm(3) which is competitive to packed beds made of commercially available zeolite 13X beads (∼1.28 mmol/cm(3)). Combined with the faster CO2 uptake showing an adsorption of 50% within 5-8 s (beads ∼10 s), the monoliths show great potential for pressure swing adsorption applications, where high volumetric working capacities, fast uptakes, and low pressure drops are needed for a high system performance.
Strong
hierarchical porous zeolite structures are prepared by a
sol–gel method using freeze gelation. Instead of conventional
binders in powder form, such as bentonite or kaolin, it has been proven
that using a freeze gelation method based on a colloidal silica sol
is a more straightforward and easier-to-use-approach in fabricating
highly mechanically stable zeolite monoliths. The resulting zeolite
slurries possess superior rheological properties (not being pseudoplastic)
and show low viscosities. This low viscosity of the slurry enables
an increase in the solid content without compromising the extraordinary
good flow behavior for casting applications. Additionally, in comparison
to conventional powdery binders, zeolite samples prepared by using
a colloidal silica sol exhibit a significantly higher mechanical strength.
This mechanical strength can be further improved by either increasing
the zeolite content or increasing the silica to zeolite ratio. Increasing
the zeolite content leads to an increased volumetric adsorption capacity
for CO
2
as the test gas, resulting from the increased amount
of zeolite particles per unit volume. In addition, a higher solid
content of the zeolite monoliths leads to higher compression strengths,
while showing the same elastic deformation and brittle failure characteristics.
In turn, increasing the silica to zeolite ratio does not affect the
volumetric adsorption capacity for CO
2
. Nevertheless, higher
silica contents lead to a significant increase in the elastic deformation
and absorbed work until failure. Therefore, the proposed processing
route based on freeze gelation presents an easy and unique tool to
tune the mechanical and gas adsorptive properties of hierarchically
structured zeolite monoliths, according to the application requirements.
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