Abstract: A method of monitoring a strengthening process of a chemically active material having a liquid phase and a non-liquid phase, the method comprises: (a) continuously measuring at least one physical parameter characterizing the liquid phase; (b) extracting a time-dependence of the at least one physical parameter, so as to identify functional transitions in the time-dependence; and (c) using the functional transitions to determine a strengthening state of the chemically active material; thereby monitoring the strengthening process of the chemically active material.

Abstract: A method of forecasting strength of a chemically active material while hardening is disclosed. The chemically active material is characterized by at least one physical parameter. The method comprises: (a) measuring the at least one physical parameter over a predetermined time-interval, so as to obtain at least one series of measurements; (b) extracting a predetermined time-dependence of the at least one physical parameter over at least a portion of the predetermined time-interval; and (c) using the predetermined time-dependence of the at least one physical parameter to forecast the strength of the chemically active material at a future time.

Abstract: A method of monitoring a strengthening process of a chemically active material having a liquid phase and a non-liquid phase, the method comprises: (a) continuously measuring at least one physical parameter characterizing the liquid phase; (b) extracting a time-dependence of the at least one physical parameter, so as to identify functional transitions in the time-dependence; and (c) using the functional transitions to determine a strengthening state of the chemically active material; thereby monitoring the strengthening process of the chemically active material.

Abstract: A method of forecasting strength of a chemically active material while hardening is disclosed. The chemically active material is characterized by at least one physical parameter. The method comprises: (a) measuring the at least one physical parameter over a predetermined time-interval, so as to obtain at least one series of measurements; (b) extracting a predetermined time-dependence of the at least one physical parameter over at least a portion of the predetermined time-interval; and (c) using the predetermined time-dependence of the at least one physical parameter to forecast the strength of the chemically active material at a future time.

Abstract: A method of measuring a strength of a capillary-porous chemically active material while hardening, the capillary-porous chemically active material including therein a liquid which undergoes metamorphosis and which is present in the capillary-porous chemically active material in different stages during curing, the method is effected by performing a high frequency, spin-echo nuclear magnetic resonance measurement of each stage of the liquid; and correlating the high frequency, spin-echo nuclear magnetic resonance measurement with a predetermined relationship between the strength and the high frequency, spin-echo nuclear magnetic resonance measurement.