Photometer/nephelometer device and method of using to determine proppant concentration

What is claimed is: 1. A feedback control method for adjusting the proppant concentration in a fracturing fluid that is utilized in stimulation of an underground formation, comprising: supplying proppant or proppant slurry from proppant reservoir to a fluid stream; combining the proppant or proppant slurry with the fluid forming a fracturing fluid containing proppant and measuring the concentration of the proppant in said fracturing fluid downstream by a concentration meter, wherein the concentration meter is a photometer/nephelometer device utilizing optical light; providing a feedback signal to a computer; and changing the concentration of the fracturing fluid based on the feedback signal of the concentration meter. 2. The feedback control method of claim 1 , wherein the photometer/nephelometer device utilizes near-infrared light. 3. The feedback control method of claim 1 , wherein the photometer/nephelometer device utilizes visible light. 4. The feedback control method of claim 1 , wherein the photometer/nephelometer device utilizes ultraviolet light. 5. The feedback control method of claim 1 , wherein the photometer/nephelometer device measures the amount of light attenuated by the proppant in the fracturing fluid. 6. The feedback control method of claim 1 , wherein the photometer/nephelometer device measures the amount of light scattered by the proppant in the fracturing fluid. 7. The feedback control method of claim 1 , wherein the signal from the photometer/nephelometer device is transformed into a concentration in a PLC. 8. The feedback control method of claim 7 , wherein the PLC is employed to manipulate a mixing/control system to arrive at a desired concentration. 9. A feedback control method for adjusting the proppant concentration in a fracturing fluid that is utilized in stimulation of an underground formation, comprising: supplying proppant or proppant slurry from a sealed, pressurized proppant reservoir to a motive fluid stream wherein the pressurized proppant reservoir is in a position to supply the proppant slurry to at least one eductor; supplying a motive fluid flow of liquefied gas at pressure between about 150 to 400 psig to the at least one eductor, wherein the liquefied gas is mixed with proppant or proppant slurry to form a fracturing fluid containing proppant and measuring a concentration of the proppant in said fracturing fluid downstream by a photometer/nephelometer device; providing a signal to a computer from the photometer/nephelometer device; changing the concentration of the fracturing fluid based on the reading of the photometer/nephelometer device by sending a signal from the computer to route a pressurized fluid to the proppant reservoir thereby manipulating the pressure in said proppant reservoir or by sending a signal to a control valve disposed between the eductor and the proppant reservoir, and control the proppant concentration from about 0.1 to 10 lbs/gal of proppant in the fracturing fluid. 10. The feedback control method of claim 9 , wherein the photometer/nephelometer device utilizes near-infrared light. 11. The feedback control method of claim 9 , wherein the photometer/nephelometer device utilizes visible light. 12. The feedback control method of claim 9 , wherein the photometer/nephelometer device utilizes ultraviolet light. 13. The feedback control method of claim 9 , wherein the photometer/nephelometer device measures the amount of light attenuated by the proppant in the fracturing fluid. 14. The feedback control method of claim 9 , wherein the photometer/nephelometer device measures the amount of light scattered by the proppant in the fracturing fluid. 15. The feedback control method of claim 9 , wherein the signal from the photometer/nephelometer device is transformed into a concentration in the computer. 16. The feedback control method of claim 15 , wherein the computer is employed to manipulate a mixing/control system to arrive at a desired concentration.