System and method for determining the current condition of power contacts

What is claimed is: 1. A system for determining a current condition of a power contact in an electrical contactor comprising: a power contact having a movable contact supported on a bridge and a fixed contact; a first auxiliary contact having a movable contact supported on a bridge and a fixed contact; a second auxiliary contact having a movable contact supported on a bridge and a fixed contact; a contact carrier supporting the movable power contact bridge, the first auxiliary movable contact bridge and the second auxiliary movable contact bridge such that the movable contacts move in unison and such that the movable contacts of the first and second auxiliary contacts are spaced apart by a first fixed distance and the movable contact of the second auxiliary contact and the movable power contact are spaced apart by a second fixed distance; a controller having a processor and a non-tangible memory, the first fixed distance, the second fixed distance, contactor characteristics and an algorithm for determining the current condition of the power contact being previously stored in the non-tangible memory, the processor receiving a binary signal from each of the power contact, the first auxiliary contact and the second auxiliary contact indicating the opening or closing of their respective movable contacts and storing each binary signal received from the power contact, the first auxiliary contact and the second auxiliary contact in the non-tangible memory; and, wherein the algorithm, being executed by the processor, determines the current condition of the power contact based on the stored binary signals, the fixed distances and the previously stored contactor characteristics, the processor notifying a preventive maintenance system and/or a user that preventive maintenance on the contactor is required when the determined current condition of the power contact has exceeded a predetermined wear limit. 2. The system of claim 1 , wherein the determined current condition of the power contacts can include one or more of a percent of remaining contact life, an amount of remaining power contact material or a number of remaining contactor operations. 3. The system of claim 1 , wherein the current condition of the power contact is determined by: determining a speed of the contact carrier; determining an expected closing/opening time of the power contact; sensing an actual closing/opening time of the power contact, and; determining, from the determined contact carrier speed, the determined expected power contact closing/opening time, the sensed actual power contact closing/opening time and the previously stored contactor characteristics, one or more of a percent of remaining power contact life, a contact wear factor, an amount of remaining power contact material or a number of remaining contactor operations. 4. The system of claim 3 , wherein the speed of the contact carrier is determined from the binary signals of the first auxiliary contact and the second auxiliary contact and the first fixed distance. 5. The system and method of claim 3 , wherein the expected power contact closing/opening time is determined from the determined contact carrier speed and the second fixed distance. 6. The system of claim 1 , wherein the first auxiliary contact can be one of a normally open contact or a normally closed contact and the second auxiliary contact can be the other of a normally open or a normally closed contact. 7. The system of claim 1 , wherein the previously stored contactor characteristics can include determined/learned characteristics such as an initial or immediately preceding contact carrier speed, an initial or immediately preceding time between the first auxiliary contact opening or closing and the second auxiliary contact opening or closing, an initial or immediately preceding time between the second auxiliary contact opening or closing and the power contact opening or closing, an initial or immediately preceding expected power contact closing/opening time or a number of lifetime contactor operations. 8. The system of claim 7 , wherein the initial contact carrier speed, the initial time between the first auxiliary contact opening or closing and the second auxiliary contact opening or closing, the initial time between the second auxiliary contact opening or closing and the initial power contact opening or closing time and the number of life time contactor operations can be determined/learned during a predetermined number of initial operations of the contactor or provided by the contactor manufacturer based on product development testing or a Design of Experiments (DOE) process. 9. The system and method of claim 1 , wherein the previously stored contactor characteristics can include measured or provided characteristics such as the first fixed distance, the second fixed distance, an initial dimension between the movable power contact and the fixed power contact when the power contacts are in a stable open state or an initial thickness of the combined movable and fixed power contacts. 10. The system of claim 1 , wherein the predetermined wear limit can be established by the user. 11. The system of claim 1 , wherein the predetermined wear limit is selected such that notifying the preventive maintenance system and/or user is sufficiently ahead of a potential power contact failure that an acceptable maintenance down time of the contactor and affected equipment can be scheduled. 12. The system of claim 1 , wherein the controller can be a part of the contactor or located at a remote location. 13. The system of claim 12 , wherein the controller can be a programmable logic controller (PLC) or any “smart” device capable of executing the algorithm. 14. The system of claim 1 , wherein an auxiliary contact operator supporting the movable contacts of the first and second auxiliary contacts is enclosed in a housing provided with means for attaching to an existing contactor, the auxiliary contact operator having an extended end with provisions for attaching to the contact carrier of the existing contactor such that the movable contacts of the first and second auxiliary contacts move in unison with the movable contact of the existing contactor. 15. A method for determining a current condition of a power contact in an electrical contactor comprising: retrieving, by a processor, from a non-tangible memory associated with the processor, one or more characteristics of the contactor and an algorithm for determining the current condition of the power contact; determining, by the processor, a closing/opening speed of a contact carrier of the electrical contactor; determining, by the processor, an expected closing/opening time for a movable power contact supported on the contact carrier; sensing, by the processor, an actual closing/opening time of the movable power contact; determining, by the processor, the current condition of the power contact using the determined contact carrier speed, the determined expected closing/opening time of the movable power contact, the sensed actual closing/opening time of the movable power contact and the one or more characteristics of the contactor; and notifying, by the processor, a preventive maintenance system and/or a user that preventive maintenance is required when the determined current condition of the power contact has exceeded a predetermined wear limit. 16. The method of claim 15 , wherein the closing/opening speed of the contact carrier is determined from a known fixed distance between a first movable auxiliary contact supported on the contact carrier and a second movable auxiliary contac