Development of non-destructive testing method to evaluate bond condition of reinforced concrete beam

The invention claimed is: 1. A method for non-destructive testing of a bond condition of concrete beams reinforced by steel rods, comprising: applying, by a transmitting transducer of an ultrasonic tester, ultrasonic pulses to a concrete beam; receiving, by a receiving transducer, vibrational waves reflected from the steel rods at a plurality of reading locations along the concrete beam; measuring a transit time of the vibrational waves received at each reading location; determining a pulse velocity of each vibrational wave received at each reading location; determining a highest pulse velocity of the vibrational waves at each reading location; comparing the highest pulse velocity of the vibrational waves received at a reading location to a first reference pulse velocity; and identifying a bond condition of cracking around a steel rod at a testing location when the highest pulse velocity at the testing location is less than the first reference pulse velocity; determining a peak load carrying capacity (P peak ) of the concrete beam by: applying a force perpendicular to a center of a length of the concrete beam; applying ultrasonic pulses to the concrete beam; determining the highest pulse velocity at each reading location; increasing a magnitude of the force by increments; determining the highest pulse velocity at each reading location for each incremental increase in the magnitude of the force; and determining the peak load carrying capacity (P peak ) of the concrete beam when the highest pulse velocity at one of the reading locations is less than a second reference pulse velocity. 2. The method of claim 1 , comprising predicting, by an artificial neural network, a width of each crack formed around the bonds in the concrete. 3. The method of claim 1 , further comprising: marking the concrete beam with a grid having two rows and a plurality of columns; wherein an intersection of a row with a column defines a reading location. 4. The method of claim 3 , wherein: a first row is parallel to and separated from a second row by a distance in the range of 140 mm to 160 mm; and each column is parallel to an adjacent column and separated from the adjacent column by a distance in the range of 90 mm to 110 mm. 5. The method of claim 3 , further comprising: determining the first reference pulse velocity at each reading location by measuring the highest pulse velocity when the force applied to the concrete beam is zero. 6. The method of claim 3 , further comprising: marking the reading locations on a first row parallel to a length of a first steel rod within the concrete beam; and marking the reading locations on a second row parallel to a length of a second steel rod within the concrete beam. 7. The method of claim 1 , further comprising: attaching the receiving transducer to the concrete beam at a location perpendicular to a length of the steel rods; and contacting the transmitting transducer to the concrete beam at each of the plurality of reading locations. 8. A non-destructive ultrasonic testing method of a bond condition of a concrete beam reinforced by steel rods, comprising: applying, by a transmitting transducer of an ultrasonic tester, ultrasonic pulses to a concrete beam; receiving, by a receiving transducer, vibrational waves reflected from the steel rods at a plurality of reading locations along the concrete beam; measuring a transit time of the vibrational waves received at each reading location; determining a pulse velocity of each vibrational wave received at each reading location; determining a highest pulse velocity of the vibrational waves at each reading location, the highest pulse velocity at each reading location defining a first reference pulse velocity at the reading location; determining a peak load carrying capacity (P peak ) of the concrete beam by applying a force perpendicular to a center of a length of the concrete beam; applying a second set of ultrasonic pulses to the concrete beam; measuring the highest pulse velocity at each reading location received from the second set of ultrasonic pulses; increasing a magnitude of the force by increments; measuring the highest pulse velocity at each reading location for each incremental increase in the magnitude of the force; and determining the peak load carrying capacity (P peak ) of the concrete beam when the highest pulse velocity at one of the reading locations is less than a second reference pulse velocity, wherein the second reference pulse velocity is less than the first reference pulse velocity. 9. The non-destructive ultrasonic testing method of claim 8 , further comprising: comparing the highest pulse velocity of the vibrational waves received at a reading location to the second reference pulse velocity; and identifying a bond condition of cracking around a steel rod at a testing location when the highest pulse velocity at the testing location is less than the second reference pulse velocity. 10. The non-destructive ultrasonic testing method of claim 9 , further comprising: marking the concrete beam with a grid having two rows and a plurality of columns, wherein an intersection of a row with a column defines a reading location. 11. The non-destructive ultrasonic testing method of claim 8 , further comprising: marking the concrete beam with a grid having two rows and a plurality of columns; wherein an intersection of a row with a column defines a reading location. 12. The non-destructive ultrasonic testing method of claim 11 , further comprising: performing an ultrasonic velocity test of the concrete beam by: attaching the receiving transducer to the concrete beam at a location perpendicular to a length of the steel rods; and contacting the transmitting transducer to the concrete beam at each of the plurality of reading locations. 13. A system for non-destructive testing of a bond condition of concrete beams reinforced by steel rods, comprising: a transducing transmitter; a transducing receiver; an ultrasonic pulse generator configured to generate drive signals for the transducing transmitter and receive a plurality vibrational waves at the transducing receiver; a computing device including: a measurement circuit configured to record a transit time for each vibrational wave and divide a distance between the transducing transmitter and the transducing receiver by the transit time to determine a pulse velocity of each vibrational wave; a comparison circuit configured to identify a highest pulse velocity of the vibrational waves and compare each highest pulse velocity to a first reference pulse velocity; and a decision circuit configured to identify a compromised bond condition around a steel rod when the highest pulse velocity is less than the first reference pulse velocity; and a peak load testing device including: a first support configured to support a first bottom end of the concrete beam; a second support configured to support a second bottom end of the concrete beam; a force applicator configured to provide a variable force to a top center of the concrete beam; and wherein the computing device is further configured to record measurements of the pulse velocities at a plurality of reading locations for each change in the variable force and identify an amplitude of the variable force at which the highest pulse velocity is less than a second reference pulse velocity, wherein the second reference pulse velocity indicates a bond condition of cracking of the concrete around a steel rod.