Vacuum generator/amplifier for gas applications and brake booster generation method

What is claimed is: 1. An aspirator assembly comprising: a multi-lumen defining amplifier member defining a fluid passage comprising: a converging section leading to a throat, said converging section has a sinusoidal cross sectional shape leading to said throat; a step portion located adjacent said throat; a straight section located adjacent to said step portion; a diverging section located adjacent to said straight section; and an output vacuum port extending from a sidewall of said multi-lumen defining amplifier member for providing output vacuum, said output vacuum port being located after the throat and at the beginning of the straight section. 2. The aspirator assembly of claim 1 , wherein said throat includes a minimum internal lumen diameter D. 3. The aspirator assembly of claim 2 , wherein said step is introduced immediately after the throat. 4. The aspirator assembly of claim 3 , wherein said step includes an internal lumen diameter in the range of 1.1 D to 1.5 D. 5. The aspirator assembly of claim 2 , wherein said fluid passage is aligned along a central flow axis. 6. The aspirator assembly of claim 5 , wherein said sinusoidal cross sectional shape of said converging section extends a length in the range of 1 D to 4 D along said central flow axis. 7. The aspirator assembly of claim 5 , wherein said straight section extends a length in the range of 3 D to 8 D along said central flow axis. 8. The aspirator assembly of claim 2 , wherein said diverging section extends a length in the range of 12 D to 15 D along said central flow axis. 9. The aspirator assembly of claim 2 , wherein said sinusoidal shape is particularly effective in converting pressure energy to kinetic energy and minimizing friction losses by using a short converging length of 1 D-4 D. 10. The aspirator assembly of claim 2 , wherein said step defines a transversely projecting annular wall segment having a radial extent or diameter of 1.1 D to 1.5 D, in order to generate higher amplification or gain ratios, arid wherein the throat, which terminates distally in the step, defines the beginning of the straight section. 11. The aspirator assembly of claim 1 , wherein said straight section defines an inner wall shaped in the form of a cylinder. 12. The aspirator assembly of claim 1 , wherein said diverging section defines an inner wall shaped with a tapered angle relative to said straight section wherein said tapered angle is in the range of 3° to 8°. 13. The aspirator assembly of claim 1 , wherein said output vacuum port extends generally normal from the longitudinal axis and includes a bore section and a tapered section wherein the bore section directly communicates with the straight section. 14. An aspirator system comprising: a multi-lumen defining amplifier member in communication with a multi-port housing configured for connection through tube sections to a vacuum reservoir; said a multi-lumen defining amplifier member defining a fluid passage comprising: a converging section leading to a throat, said converging section has a sinusoidal cross-sectional shape leading into said throat; a step portion located adjacent said throat; a straight section located adjacent to said step portion; a diverging section located adjacent to said straight section; and an output vacuum port extending from a sidewall of said multi-lumen defining amplifier member for providing amplified output vacuum, said output vacuum port being located after the throat; wherein amplified vacuum pressure is communicated via the output vacuum port to at least one check valve assembly to a tubular member of the multi-port housing. 15. The aspirator system of claim 14 , wherein said tubular member includes an open continuous lumen terminating at opposing ends. 16. The aspirator system of claim 15 , wherein said opposing ends include barb connectors adapted for connection to a vacuum tube. 17. The aspirator system of claim 14 , wherein said straight section includes a proximal end adjacent the throat and a distal end adjacent the divergent section, wherein said output vacuum port is positioned adjacent the proximal end of said straight section. 18. An aspirator assembly comprising: a multi-lumen defining amplifier member defining a fluid passage along a central flow axis comprising: a converging section leading to a throat, said throat includes a minimum internal lumen dimension D; a step portion located adjacent said throat, wherein said step defines a transversely projecting annular wall segment; a straight section located adjacent to said step portion wherein the throat, which terminates distally in the step portion, defines the beginning of the straight section, said straight section includes a proximal end adjacent the throat and an opposite distal end; a diverging section located adjacent to said distal end of said straight section; and an output vacuum port extending from a sidewall of said multi-lumen defining amplifier member for providing output vacuum, said output vacuum port being located after the throat. 19. The aspirator assembly of claim 18 , wherein said output vacuum port is positioned adjacent the proximal end of said straight section. 20. The aspirator assembly of claim 18 , wherein said converging section includes a sinusoidal cross sectional shape wherein said sinusoidal cross-sectional shape of said converging section extends a length in the range of 1 D to 4 D along said central flow axis wherein said step portion includes a radial diameter of 1.1 D to 1.5 D, in order to generate higher amplification or gain ratios.