System and method for sidestream mixing

We claim: 1. A system for removing at least a portion of a process fluid stream, comprising: at least one driver comprising a drive shaft, the at least one driver configured to provide the drive shaft with rotational energy; a first compressor comprising a rotary shaft, the rotary shaft being operatively coupled to the drive shaft and configured such that the rotational energy from the drive shaft is transmitted to the rotary shaft; a second compressor comprising a rotary shaft, the rotary shaft of the second compressor being operatively coupled to the drive shaft and configured such that the rotational energy from the drive shaft is transmitted to the rotary shaft of the second compressor; a first junction formed from a first plurality of conduits comprising: a first conduit fluidly coupling the first compressor and the second compressor, the first conduit forming a first conduit diameter and configured to flow therethrough the process fluid stream; and a second conduit fluidly coupled to the first conduit and a first external component, the second conduit configured to flow therethrough at least a first portion of the process fluid stream, wherein the first junction is disposed between the first compressor and the second compressor at a first distance at least three times the diameter of the first conduit upstream of at least one of the first compressor or the second compressor, such that the at least a first portion of the process fluid stream is removed from the process fluid stream and fed to the first external component via the second conduit; a third compressor comprising a rotary shaft and a fourth compressor comprising a rotary shaft, wherein the at least one driver comprises: a first driver comprising a first drive shaft comprising a first drive shaft first end and a first drive shaft second end, the first drive shaft first end being integral with or coupled to the rotary shaft of the first compressor and the first drive shaft second end being integral with or coupled to the rotary shaft of the second compressor; a second driver comprising a second drive shaft comprising a second drive shaft first end and a second drive shaft second end, the second drive shaft first end being integral with or coupled to the rotary shaft of the third compressor and the second drive shaft second end being integral with or coupled to the rotary shaft of the fourth compressor; a second junction formed from a second plurality of conduits comprising: a third conduit fluidly coupling the second compressor and the third compressor, the third conduit forming a second conduit diameter and configured to flow therethrough the process fluid stream; and a fourth conduit fluidly coupled to the third conduit and at least one of the first external component and a second external component, the fourth conduit configured to flow therethrough at least a second portion of the process fluid stream; and wherein the second junction is disposed between the second compressor and the third compressor at a second distance at least three times the diameter of the third conduit upstream of the third compressor, such that the at least a second portion of the process fluid stream is removed from the process fluid stream and fed to the at least one of the first external component and the second external component via the fourth conduit. 2. The system of claim 1 , further comprising: a third junction formed from a third plurality of conduits comprising: a fifth conduit fluidly coupling the third compressor and the fourth compressor, the fifth conduit forming a third conduit diameter and configured to flow therethrough the process fluid stream; and a sixth conduit fluidly coupled to the fifth conduit and at least one of the first external component, the second external component, and a third external component, the sixth conduit configured to flow therethrough at least a third portion of the process fluid stream, wherein the third junction is disposed between the third compressor and the fourth compressor at a third distance at least three times the diameter of the fifth conduit upstream of the fourth compressor, such that the at least a third portion of the process fluid stream is removed from the process fluid stream and fed to the at least one of the first external component, the second external component, and the third external component via the sixth conduit. 3. The system of claim 1 , further comprising a third compressor comprising a rotary shaft and a fourth compressor comprising a rotary shaft, wherein the drive shaft is operatively coupled to a plurality of gears, such that the plurality of gears transmit rotational energy from the drive shaft to the rotary shafts of the respective first compressor, second compressor, third compressor and fourth compressor. 4. The system of claim 3 , wherein the plurality of gears comprises: a first gear integral with or coupled to the drive shaft; a second gear integral with or coupled to the rotary shaft of the first compressor and the second compressor; and a third gear integral with or coupled to the rotary shaft of the third compressor and the fourth compressor, wherein the first gear is operatively coupled to the second gear and the third gear. 5. The system of claim 4 , wherein the first gear is a bull gear, the second gear is a first pinion, and the third gear is a second pinion, each of the first pinion and the second pinion having an identical gearing ratio with the bull gear. 6. The system of claim 5 , wherein the first gear is a bull gear, the second gear is a first pinion, and the third gear is a second pinion, each of the first pinion and the second pinion having different gearing ratios with the bull gear. 7. The system of claim 6 , further comprising: a second junction formed from a second plurality of conduits comprising: a third conduit fluidly coupling the second compressor and the third compressor, the third conduit forming a second conduit diameter and configured to flow therethrough the process fluid stream; and a fourth conduit fluidly coupled to the third conduit and at least one of the first external component and a second external component, the fourth conduit configured to flow therethrough at least a second portion of the process fluid stream, wherein the second junction is disposed between the second compressor and the third compressor at a second distance at least three times the diameter of the third conduit upstream of the third compressor, such that the at least a second portion of the process fluid stream is removed from the process fluid stream and fed to the at least one of the first external component and the second external component via the fourth conduit. 8. The system of claim 7 , further comprising: a third junction formed from a third plurality of conduits comprising: a fifth conduit fluidly coupling the third compressor and the fourth compressor, the fifth conduit forming a third conduit diameter and configured to flow therethrough the process fluid stream; and a sixth conduit fluidly coupled to the fifth conduit and at least one of the first external component, the second external component, and a third external component, the sixth conduit configured to flow therethrough at least a third portion of the process fluid stream, wherein the third junction is disposed between the third compressor and the fourth compressor at a third distance at least three times the diameter of the fifth conduit upstream of the fourth compressor, such that the at least a third portion of the process fluid stream is removed from the process fluid stream and fed to the at least one of the first external component, the second external component, and the third external component via the sixth conduit.