Starch is a bio-polymer, renewable and biodegradable material being used as a binder in the field of construction possessing better mechanical properties. However, the bio-degradation property of starch would reduce the life structure of the product. In this context, the present research explores three binder systems viz., modified cassava starch (S), cardanol novolac resin (CH) and the binder SCH obtained by blending varied percentages of modified cassava starch (S) with cardanol novolac resin (CH) to improve the properties of starch binder and to evaluate the effect of degradation and moisture resistance in the developed engineered stone. Engineered stone was made using waste foundry sand (WFS) as a filler and S/CH of three systems as a binder material. The performance of the developed stone was analyzed through physio-mechanical, thermal, microstructural, UV irradiation and anti-microbial studies. The percentage of the binder varied from 7.5 to 15wt%. The resulting WFS-SCH composite at 15% of binder showed better properties of compressive strength of 20.99 MPa, bending strength of 7.26 MPa and moisture resistance of 122 ° (water contact angle) than compared to the WFS-S composite. Based on the analysis, a blended matrix of S and CH with different cross-linkers reduced the aqueous degradation and moisture absorption of the bio-based engineered stone. The potential application, limitations and recommendations of the developed cassava-based engineered stone were discussed. The outcome of the research paves an avenue to overcome the deficient characteristics of starch and provides an effective method for the utilization of solid waste material over natural resources.