Abstract: A digital precious metal testing apparatus utilizes a test pen probe having therewithin a titanium wire that generates a galvanic voltage when an electrical circuit is completed with the object being tested between the pen probe and the meter test pad. A calibration system is provided to enhance the accuracy of the testing apparatus by comparing a test reading from a known test specimen with a corresponding theoretical reading for that specimen, and generating a recalibration curve from which all subsequent readings will be compared to determine the content of precious or non-precious metal being tested. The titanium wire test pen probe generates a greater galvanic charge compared to conventional platinum wire pen probes, which enables the test pen to be used to distinguish grades of non-precious metals, such as distinguishing grade 304 stainless steel from grade 316 stainless steel, for use in the recycling industry.

Abstract: A precious metal testing apparatus determines the percentage content of precious metal in a specimen being tested by detecting the change in the rate of current flow through a resistive layer formed on the specimen by an application of a corrosive electrolyte on the specimen. The electrical circuit forms a fixed resistance circuit and a variable resistance circuit due to the formation of a growing resistive layer on the specimen such that the flow of current through the variable resistance circuit decreases as the flow of current through the fixed resistance circuit increase. The detection of the rate of change in current flow as a result of the increasing growth of the resistive layer can be compared to a look-up table that provides a corresponding percentage of precious metal in the specimen. Calibration of the testing apparatus can be accomplished with a specimen of known purity of the precious metal.

Abstract: A digital precious metal testing apparatus utilizes a probe that generates a galvanic voltage when an electrical circuit is completed with the object being tested being placed between the probe and the meter test pad formed of a copper pour with a gold coating. A microprocessor signals the percentage of precious metal through an indicator bar of LEDs. A calibration system is provided to enhance the accuracy of the testing apparatus by comparing a test reading from a known test specimen with a corresponding theoretical reading for that specimen. The calibration procedure establishes a recalibration curve from the test reading against which all subsequent readings will be compared to determine the content of precious metal. Calibration of the testing apparatus is initiated with the depression of a calibration switch and is undertaken with each power-up of the meter, with each probe replacement and with any substantial change in environmental conditions.

Abstract: A precious metal testing apparatus determines the percentage content of precious metal in a specimen being tested by detecting the change in the rate of current flow through a resistive layer formed on the specimen by an application of a corrosive electrolyte on the specimen. The electrical circuit forms a fixed resistance circuit and a variable resistance circuit due to the formation of a growing resistive layer on the specimen such that the flow of current through the variable resistance circuit decreases as the flow of current through the fixed resistance circuit increase. The detection of the rate of change in current flow as a result of the increasing growth of the resistive layer can be compared to a look-up table that provides a corresponding percentage of precious metal in the specimen. Calibration of the testing apparatus can be accomplished with a specimen of known purity of the precious metal.

Abstract: A digital precious metal testing apparatus utilizes a probe that generates a galvanic voltage when an electrical circuit is completed with the object being tested being placed between the probe and the meter test pad formed of a copper pour with a gold coating. A microprocessor signals the percentage of precious metal through an indicator bar of LEDs. A calibration system is provided to enhance the accuracy of the testing apparatus by comparing a test reading from a known test specimen with a corresponding theoretical reading for that specimen. The calibration procedure establishes a recalibration curve from the test reading against which all subsequent readings will be compared to determine the content of precious metal. Calibration of the testing apparatus is initiated with the depression of a calibration switch and is undertaken with each power-up of the meter, with each probe replacement and with any substantial change in environmental conditions.