Method for evaluating anchor bolt embedment in concrete

The invention claimed is: 1. A non-destructive testing method for evaluating the pullout load capacity and bond quality for an anchor bolt embedded in concrete, comprising: centering a plunger of a Schmidt hammer on the anchor bolt; impacting the anchor bolt with the plunger of the Schmidt hammer; measuring a rebound number of the anchor bolt embedded in the concrete with the Schmidt hammer; transmitting the rebound number to a controller connected to the Schmidt hammer; measuring an ultrasonic pulse transit time in the concrete surrounding the anchor bolt by using an ultrasonic pulse velocity tester; measuring an angle of inclination of the plunger with a digital level connected to Schmidt hammer; correcting the rebound number based on the angle of inclination of the plunger; transmitting the corrected rebound number to the controller; estimating the pull out load carrying capacity of the installed anchor bolt by correlating the rebound number with the ultrasonic transit time; and evaluating the bond quality of the embedded anchor bolt with the concrete. 2. The non-destructive testing method of claim 1 , wherein measuring a rebound number further comprises driving an impact mass along a central axis of the Schmidt hammer to impact the plunger; impacting the anchor bolt with the convex distal tip of the plunger; measuring the rebound distance of the mass; and generating a rebound number based on the rebound distance. 3. The non-destructive testing method of claim 1 , wherein measuring an ultrasonic pulse transit time comprises contacting the concrete at a first location surrounding the anchor bolt with a transmitting transducer; contacting the concrete at a second location surrounding the anchor bolt and spaced from the first location with a receiving transducer; generating an ultrasonic pulse with the transmitting transducer at a first time; receiving the ultrasonic pulse with the receiving transducer at a second time later than the first time, the receiving transducer generating an electrical signal in response to receiving the ultrasonic pulse; calculating the ultrasonic pulse transit time by subtracting the first time from the second time; recording the ultrasonic pulse transit time in a memory of the ultrasonic pulse velocity tester; and displaying the ultrasonic pulse transit time on a display of the ultrasonic pulse velocity tester. 4. The non-destructive testing method of claim 3 , further comprising transmitting the ultrasonic pulse transit time to a controller connected to the ultrasonic pulse velocity tester, wherein the controller is at least one of connected wirelessly to the ultrasonic pulse velocity tester and connected by wiring to the ultrasonic pulse velocity tester. 5. The non-destructive testing method of claim 4 , wherein estimating the pull out load capacity of the embedded anchor bolt further comprises receiving the Schmidt hammer rebound number at the controller, wherein the controller includes a database, a memory, a processor, a transceiver and a receiver; retrieving, from data stored in the database, an embedment length, an anchor bolt diameter and a concrete strength; combining the Schmidt hammer rebound number, R, with the embedment length, Ld, anchor bolt diameter, Bd, and concrete strength, Cs, to generate a vector x, where x={R, Le, Bd, Cs}; receiving the transit time, TT, from the ultrasonic pulse velocity tester at the controller; combining the transit time with the with the vector x to generate a vector y, where y={R, Le, Bd, Cs, TT}; matching the vector y with a record from a look up table stored in the database, wherein the lookup table record relates the vector y to a pull out load capacity. 6. The non-destructive testing method of claim 4 , wherein evaluating the bond quality of the embedded anchor bolt with the concrete structure comprises receiving the Schmidt hammer rebound number at the controller, wherein the controller includes a database, a memory, a processor, a transceiver and a receiver; retrieving, from data stored in the database, an embedment length, anchor bolt diameter and concrete strength; combining the Schmidt hammer rebound number, R, with the embedment length, Ld, anchor bolt diameter, Bd, and concrete strength, Cs, to generate a vector x, where x={R, Le, Bd, Cs}; receiving the transit time, TT, at the controller, from the ultrasonic pulse velocity tester; comparing the transit time, TT, to ultrasonic pulse transit time thresholds stored in the database, the ultrasonic pulse transit time thresholds related to porosity, P, internal cracking, IC, air voids, AV, and water pockets, W, around the embedded anchor bolt; generating a vector z, where z i ={TT, P i , IC i , AV i , W i } and P i =1 if TT≥P and P i =0 if TT≤P, IC i =1 if TT≥IC and IC i =0 if TT≤IC, AV i =1 if TT≥AV and AV i =0 if TT≤AV, and P i =1 if TT≥P and P i =0 if TT≤P; where i is an integer; adding the vector z to the vector x to generate a vector k, where k={R, Ld, Bd, Cs, TT, P i , IC i , AV i , W i }; matching the vector k with a record from a look up table stored in the database, wherein the lookup table record relates the values of the vector k to the bond quality of the embedded anchor bolt with the concrete structure. 7. The non-destructive testing method of claim 6 , further comprising measuring the angle of inclination of the plunger with the digital level; correcting the rebound number based on the angle of inclination; displaying the corrected rebound number and the angle of inclination on a display of the Schmidt hammer; transmitting the corrected rebound number, Rc, to the controller; generating a vector k c , where k c ={R, Le, Bd, Cs, TT, P i , IC i , AV i , W i }; matching the vector k c with a record from a look up table stored in the database, wherein the lookup table record relates the values of the vector k c to the bond quality of the embedded anchor bolt with the concrete structure.