Side-stream foam monitor and control system

What is claimed: 1. A method for continuous on-line, real time, measurement, delivery and control of foaming of a process fluid comprising: providing a continuous stream of process fluid ( 1 ) as a side stream ( 3 ) to a foam cell vessel ( 8 ) having an inlet and outlet; maintaining a constant level of process fluid in the foam cell vessel by simultaneously draining through the outlet an equal amount of process fluid ( 1 ) from the foam cell vessel ( 8 ) as is entering the foam cell vessel ( 15 ); wherein the process fluid flows through the inlet and cascades into the foam cell vessel, thereby entraining air and creating a level of accumulated foam on the surface of the process fluid in the foam cell vessel ( 8 ); and wherein the outlet is configured so as not to disrupt the water level being maintained or carry away any accumulated foam in the foam cell vessel; measuring and monitoring the height of the accumulated foam using a non-contact optical distance measurement device ( 16 ) capable of providing an electronic output signal proportional to the level of foam in the foam cell vessel; and delivering a defoamer to the process fluid dependent upon whether the level of foam is below, at or above a pre-determined set point. 2. The method according to claim 1 , further comprising introducing compressed air into the constant fluid level of the foam cell vessel or introducing air into the process fluid side stream. 3. The method according to claim 1 , wherein the non-contact optical distance measurement sensor is a “reflective model-photoelectric sensor”. 4. The method according to claim 1 , where the foam cell vessel is cylindrical, conical, ovoid, sphere, conical flash, spherical flask, cube or box shaped. 5. The method according to claim 1 , wherein a flow meter is used to monitor the fluid flow rate into or out of the foam cell vessel. 6. The method according to claim 1 , further comprising one or more temperature, pH and conductivity sensors and probes. 7. The method according to claim 1 , wherein a variable speed pump is used to deliver the process fluid side stream to the foam cell vessel. 8. The method according to claim 1 , wherein a flow control valve is used to maintain a constant flow rate to the foam cell vessel. 9. The method of claim 1 , further comprising adding pigments, dyes, and fluorescing agents to the process fluid side stream. 10. The method according to claim 1 , wherein a dehumidifying device is used to control condensation in the sensing area. 11. The method according to claim 1 , further comprising automatically actuated valves to periodically dump and refill the foam cell vessel. 12. The method according to claim 1 , wherein the microprocessor uses any combination of proportional, integral or derivative (PID) control to control the defoamer feed. 13. The method according to claim 1 , wherein an alarm sounds when no variation is detected in the foam height over a certain period of time. 14. The method according to claim 1 , wherein the side-stream ( 3 ) of the process fluid ( 1 ) is recirculated through the foam cell vessel. 15. The method according to claim 1 , wherein the side-stream ( 3 ) of the process fluid ( 1 ) is selected from the group consisting of an activated sludge aeration system, a pulp mill brown stock washer system, a paper machine system, an aerated settling basin, a waste water effluent stream, a trench leading to or from a wastewater treatment system, wastewater collection system, a wastewater treatment plant, a fermentation system, a washing or flume operation for food products, an open recirculating cooling water system, an air washer system, a once through cooling water system, a cooling system discharge to a waterway or pond, a mineral washing operation, a parts washing application, a mineral processing application, a mineral floatation and separation operation, a deinking frothing operation, an anaerobic or aerobic digester system, a fiberglass mat manufacturing water system, a wet scrubber system, an air stripping water system, and a thermophilic digester system. 16. A method for continuous on-line, real time, measurement, delivery and control of foaming of a process fluid stream comprising: providing a side-stream ( 3 ) of the process fluid ( 1 ) to a foam cell vessel having an inlet and outlet; wherein the foam cell vessel comprises an inner cup ( 10 ), and a tube or pipe ( 9 ) that is suspended above and extends within the cup to about 1 cm to about 25 cm of the bottom of the inner cup ( 10 ); directing the process fluid ( 1 ) of the side-stream ( 3 ) through the tube or pipe ( 9 ) into the inner cup ( 10 ) generating foam and foam accumulation ( 11 ); maintaining a constant level of the process fluid in the foam cell vessel and inner cup ( 10 ) by monitoring the flow rate of the process fluid going into or from the foam cell vessel, and wherein the outlet is configured so as not to disrupt the water level being maintained or carry away any accumulated foam from the inner cup or the foam cell vessel; emitting a signal from a non-contact optical distance measurement sensor ( 16 ), wherein the signal is reflected off of the surface of the foam and back to the measurement sensor ( 16 ); transferring the signal to a microprocessor ( 19 ) that calculates the height of the accumulated foam based on the constant level of the process fluid ( 15 ) in the inner cup; delivering a defoamer to the process fluid dependent upon whether the level of foam is below, at or above a pre-determined set point. 17. The method according to claim 1 , wherein a microprocessor is used to calculate the accumulated foam and determine the amount of defoamer to add to the process fluid.