Electronically deriving a conclusion of the condition of slurry flow in a non-vertical conduit

I claim: 1. A method of electronically deriving a conclusion of a condition of slurry flow in a non-vertical conduit having a conduit wall and which contains a slurry to flow or flowing along the conduit, the method comprising: artificially generating at a first heating point on the conduit wall, which is defined at the invert of the conduit, a first locally heated spot on an interior surface of the conduit wall, using heat delivered to the conduit wall by a first heating device at a first variable heating power level W 1 that is substantially constant over time; artificially generating at a second heating point on the conduit wall, which is defined angularly spaced from the first heating point at an angular spacing of at least 90° and which is not spaced from the first heating point along the length of the conduit but which lies in the same cross-sectional plane of the conduit as the first heating point, a second locally heated spot on the interior surface of the conduit wall using heat delivered to the conduit wall by a second heating device at a second variable heating power level W 2 that is substantially constant over time; locally measuring the temperatures of the first and second locally heated spots respectively, thereby obtaining a first temperature value T 1 and a second temperature value T 2 ; measuring, at a predetermined reference point spaced from the first and second heating points, a third reference temperature value T 3 ; communicating electronically generated signals carrying the values W 1 , W 2 , T 1 , T 2 , and T 3 to one or more electronic computing devices, which operatively receives the signals and electronically: automatically calculates a first temperature difference dT 1 between T 1 and T 3 and compares dT 1 to a reference value for dT 1 , being dT 1 ref, automatically causes the first heating device to change the heating power level W 1 delivered to the conduit wall at the first heating point if dT 1 is not equal to dT 1 ref, or not within an allowable deviation of dT 1 ref, sufficiently to change T 1 such that dT 1 is equal to dT 1 ref, or within an allowable deviation of dT 1 ref, automatically calculates a second temperature difference dT 2 between T 2 and T 3 and compares dT 2 to a reference value for dT 2 , being dT 2 ref, automatically causes the second heating device to change the heating power level W 2 delivered to the conduit wall at the second heating point if dT 2 is not equal to dT 2 ref, or not within an allowable deviation of dT 2 ref, sufficiently to change T 2 such that dT 2 is equal to dT 2 ref, or within an allowable deviation of dT 2 ref; automatically calculates a power difference dW between W 1 and W 2 and compares dW to a reference value for dW, being dWref, automatically compares W 2 to a reference value for W 2 , being W 2 ref, and automatically derives a conclusion of a condition of slurry flow prevailing in the conduit based at least on a relationship between dW and dWref and between W 2 and W 2 ref, that if an absolute value of dW is smaller than an absolute value of dWref and an absolute value of W 2 is greater than an absolute value of W 2 ref, there is unrestricted flow in the conduit, in that no flow restricting bed of solid material has formed at the invert of the conduit, if an absolute value of dW is greater than an absolute value of dWref and an absolute value of W 2 is greater than an absolute value of W 2 ref, there is partially restricted flow in the conduit, in that a flow restricting bed of solid material has formed at the invert of the conduit, and if an absolute value of W 2 is smaller than an absolute value of W 2 ref, there is restricted flow in the conduit, in that flow in the conduit has ceased. 2. The method according to claim 1 , wherein W 2 ref>0 W 2 ref>dWref>0 W 2 >W 2 ref at unrestricted flow W 1 =W 2 at unrestricted flow. 3. A slurry flow condition monitoring system for electronically deriving a conclusion of a condition of slurry flow in a non-vertical conduit having a conduit wall and which contains a slurry to flow or flowing along the conduit, the system including: a first heating device that is arranged and configured to deliver heat to the conduit wall at a first heating point on the conduit wall, which is defined at the invert of the conduit, thereby to artificially generate a first locally heated spot on an interior surface of the conduit wall by delivering heat to the conduit wall at a first variable heating power level W 1 that is substantially constant over time, and a second heating device that is arranged and configured to deliver heat to the conduit wall at a second heating point on the conduit wall, which is defined angularly spaced from the first heating point at an angular spacing of at least 90° and which is not spaced from the first heating point along the length of the conduit but which lies in the same cross-sectional plane of the conduit as the first heating point, to thereby artificially generate a second locally heated spot on an interior surface of the conduit wall by delivering heat to the conduit wall at a second variable heating power level W 2 that is substantially constant over time; first and second temperature sensors that are arranged locally and configured to measure the temperatures of the first and second heated spots respectively, thereby to obtain a first temperature value T 1 and a second temperature value T 2 ; a third temperature sensor that is arranged and configured to measure a third reference temperature at a reference point spaced away from the first and second heating points, thereby to obtain a third reference temperature value T 3 ; electronic signal generating means capable of electronically generating signals carrying the values W 1 , W 2 , T 1 , T 2 and T 3 ; and one or more computing devices in communication with the electronic signal generating means operatively configured to receive the signals carrying the values W 1 , W 2 , T 1 , T 2 and T 3 , the one or more computing devices being programmed electronically and configured to: automatically calculate a first temperature difference dT 1 between T 1 and T 3 and compare dT 1 to a reference value for dT 1 , being dT 1 ref, automatically cause the first heating device to change the heating power level W 1 delivered to the conduit wall at the first heating point if dT 1 is not equal to dT 1 ref, or not within an allowable deviation of dT 1 ref, sufficiently to change T 1 such that dT 1 is equal to dT 1 ref, or within an allowable deviation of dT 1 ref, automatically calculate a second temperature difference dT 2 between T 2 and T 3 and compare dT 2 to a reference value for dT 2 , being dT 2 ref, automatically cause the second heating device to change the heating power level W 2 delivered to the conduit wall at the second heating point if dT 2 is not equal to dT 2 ref, or not within an allowable deviation of dT 2 ref, sufficiently to change T 2 such that dT 2 is equal to dT 2 ref, or within an allowable deviation of dT 2 ref, automatically calculate a power difference dW between W 1 and W 2 and compare dW to a reference value for dW, being dWref, automatically compare W 2 to a reference value for W 2 , being W 2 ref, and automatically derive a conclusion of a condition of slurry flow prevailing in the conduit based at least on a relationship between dW and dWref and between W 2 and W 2 ref, that if an absolute value of dW is smaller than an absolute value of dWref and an absolute value of W 2 is greater than an absolute value of W 2 ref, there is unrestricted flow in the conduit, in that no flow restricting bed of solid material has formed at the invert of the conduit, if an absolute value of dW is greater than an absolute value of dWref and an absolute value of W 2 is greater than an absolute