Addition of alkaline materials to biotrickling filter or bio-filter make-up water

The invention claimed is: 1. A biotrickling filter for the treatment of contaminated air, the biotrickling filter comprising: a vessel; a contaminated air inlet in fluid communication with an internal volume of the vessel; a treated air outlet in fluid communication with the internal volume of the vessel; a media bed disposed within the vessel and in fluid communication between the contaminated air inlet and the treated air outlet; biofiltering media disposed in the media bed, the biofiltering media configured to support growth and maintenance of a population of on the biofiltering media; a water introduction system configured to introduce water from a source of water into the vessel; an alkaline material introduction system configured to introduce an alkaline material from a source of alkaline material into the vessel; a fuzzy logic-based controller configured to utilize a fuzzy logic algorithm to regulate introduction of one of the water or the alkaline material into the vessel; and a sensor configured to measure a pH of water within the vessel and to provide an indication of the pH to the fuzzy logic-based controller, the fuzzy logic algorithm using a difference between the pH of water having passed through the media bed and a predetermined pH setpoint and a change in pH of the water having passed through the media bed per unit time as input parameters, the fuzzy logic algorithm having a total of five rules and a total of five fuzzy output sets to determine an output used to control an amount of the one of the water or the alkaline material added to the biotrickling filter per unit time. 2. The biotrickling filter of claim 1 , further comprising a manually operated flow valve configured to regulate a rate of introduction of the alkaline material into the vessel. 3. The biotrickling filter of claim 1 , further comprising a sump, wherein the pH probe is disposed in the sump. 4. The biotrickling filter of claim 1 , wherein the fuzzy logic-based controller is configured to maintain the pH between about 0 and about 4. 5. The biotrickling filter of claim 4 , wherein the fuzzy logic-based controller is configured to maintain the pH between about 1.6 and about 2.2. 6. The biotrickling filter of claim 1 , wherein the alkaline material introduction system is configured to introduce the alkaline material into the vessel with the water from the source of water. 7. The biotrickling filter of claim 6 , wherein the vessel comprises a sump and the source of water is the sump. 8. The biotrickling filter of claim 7 , wherein the alkaline material introduction system is configured to introduce the alkaline material into the sump. 9. The biotrickling filter of claim 6 , wherein the source of water is a source of make-up water external to the vessel. 10. The biotrickling filter of claim 1 , wherein the alkaline material includes one or more of magnesium hydroxide, potassium hydroxide, calcium hydroxide, sodium hydroxide, potassium carbonate, and sodium carbonate. 11. The biotrickling filter of claim 1 , wherein the predetermined pH setpoint is selected to maintain the pH in the media bed within a range conducive to maintenance of a population of hydrogen sulfide oxidizing bacteria in the media bed. 12. The biotrickling filter of claim 1 , further comprising a source of nutrients configured to introduce nutrients for the bacteria into the biotrickling filter, the nutrients including one or more of nitrogen, potassium, and phosphorus compounds. 13. The biotrickling filter of claim 1 , wherein the biofiltering media is a foamed glass media. 14. The biotrickling filter of claim 1 , wherein the fuzzy logic controller is configured to perform repeated instances of controlling the amount of the one of the water or the alkaline material added to the biotrickling filter per unit time, the repeated instances separated in time by an amount of time after which a steady state pH would be re-established in the media bed after a change in the amount of the one of the water or the alkaline material added to the biotrickling filter per unit time. 15. The biotrickling filter of claim 1 , wherein the fuzzy logic algorithm utilizes a total of three fuzzy error sets and the fuzzy logic controller assigns a value of the difference between the pH of water having passed through the media bed and a predetermined pH setpoint to one or more of the three fuzzy error sets. 16. The biotrickling filter of claim 1 , wherein the fuzzy logic algorithm utilizes a total of three fuzzy error-dot sets and the fuzzy logic controller assigns a value of the change in pH of the water having passed through the media bed per unit time to one or more of the three fuzzy error-dot sets. 17. A wastewater treatment system comprising: a basin including a wastewater inlet fluidly connected to a source of wastewater; a process gas outlet configured to output sulfur-containing process gas generated by the wastewater from the basin; a source of alkaline material; and a biotrickling filter comprising: a vessel; a contaminated air inlet providing fluid communication between an internal volume of the vessel and the process gas outlet; a treated air outlet in fluid communication with the internal volume of the vessel; a media bed disposed within the vessel and in fluid communication between the contaminated air inlet and the treated air outlet; biofiltering media disposed in the media bed, the biofiltering media configured to support growth and maintenance of a population of bacteria on the biofiltering media; a water introduction system configured to introduce water from a source of water into the vessel; an alkaline material introduction system configured to introduce an alkaline material from the source of alkaline material into the vessel; a fuzzy logic-based controller configured utilize a fuzzy logic algorithm to regulate introduction of one of the water or the alkaline material into the vessel; and a sensor configured to measure a pH of a water within the vessel and to provide an indication of the pH to the fuzzy logic-based controller, the fuzzy logic algorithm using a difference between the pH of water having passed through the media bed and a predetermined pH setpoint and a change in pH of the water having passed through the media bed per unit time as input parameters, the fuzzy logic algorithm having a total of five rules and a total of five fuzzy output sets to determine an output used to control an amount of the one of the water or the alkaline material added to the biotrickling filter per unit time. 18. The wastewater treatment system of claim 17 , wherein the predetermined pH setpoint is selected to maintain the pH in the media bed within a range conducive to maintenance of a population of hydrogen sulfide oxidizing bacteria in the media bed. 19. The wastewater treatment system of claim 17 , further comprising a source of nutrients configured to introduce nutrients for the bacteria into the biotrickling filter, the nutrients including one or more of nitrogen, potassium, and phosphorus compounds. 20. The wastewater treatment system of claim 17 , wherein the biofiltering media is a foamed glass media.