Gaseous sealing manifold assembly for surgical gas delivery system

What is claimed is: 1. A manifold assembly for a surgical gas delivery system comprising: a) a three-dimensional manifold body having a horizontal top surface and a plurality of vertical side surfaces, and configured as a modular unit adapted to be enclosed within a housing of the surgical gas delivery system and including an inlet port for receiving a gas from an outlet side of a compressor and an outlet port for recirculating the gas to an inlet side of the compressor, wherein the inlet port and the outlet port are located on one of the side surfaces of the manifold body; b) a bypass valve located on the top surface of the manifold body and communicating with the inlet port and the outlet port of the manifold body through internal passageways defined within the manifold body, wherein the bypass valve includes an electro-mechanical valve actuator for dynamically controlling a flow of the gas through the bypass valve; c) an air ventilation valve located on the top surface of the manifold body and operatively associated with the inlet side of the compressor, wherein the air ventilation valve communicates with an air ventilation port provided on one of the side surfaces of the manifold body, and wherein the air ventilation valve includes an electro-mechanical valve actuator for dynamically controlling an ingress of air through the air ventilation port from an atmosphere; d) a smoke evacuation valve located on the top surface of the manifold body and operatively associated with the outlet side of the compressor, wherein the smoke evacuation valve communicates with a smoke evacuation port provided on one of the side surfaces of the manifold body, and wherein the smoke evacuation valve includes an electro-mechanical valve actuator for dynamically controlling an egress of the gas from the manifold assembly through the smoke evacuation port when the surgical gas delivery system is operating in a smoke evacuation mode; and e) a gas fill valve located on the top surface of the manifold body and operatively associated with the compressor, wherein the gas fill valve communicates with a gas fill port provided on one of the side surfaces of the manifold body, and wherein the gas fill valve includes an electro-mechanical valve actuator for dynamically controlling a receipt of the gas through the gas fill port from a source of surgical gas. 2. The manifold assembly recited in claim 1 , further comprising an over pressure relief valve located on the top surface of the manifold body and operatively associated with the compressor, the over pressure relief valve located downstream from the bypass valve for controlling a release of the gas from the manifold assembly, wherein the over pressure relief valve is a solenoid valve. 3. The manifold assembly recited in claim 1 , wherein the manifold body includes a delivery port provided on one of side surfaces of the manifold body for delivering the gas to a gas sealed access port and includes a reception port provided on one of the side surfaces of the manifold body for receiving the gas from the gas sealed access port. 4. The manifold assembly recited in claim 1 , wherein the manifold body includes a gas quality sensor located on the top surface of the manifold body and operatively associated with the outlet side of the compressor, the gas quality sensor located downstream from the bypass valve for monitoring a level of oxygen in the recirculated gas recirculating through the manifold assembly. 5. The manifold assembly recited in claim 1 , wherein the manifold body includes a first pressure sensor port located on the top surface of the manifold body and operatively associated with the inlet side of the compressor, the first pressure sensor port located downstream from the bypass valve, and a second pressure sensor port located on the top surface of the manifold body and operatively associated with the outlet side of the compressor, the second sensor port located downstream from the bypass valve. 6. The manifold assembly recited in claim 1 , wherein each electro-mechanical valve actuator is a motorized linear actuator, which includes a respective rack and pinion mechanism. 7. The manifold assembly recited in claim 6 , wherein each rack and pinion mechanism includes a horizontal actuation shaft, a horizontal drive rack gear operatively associated with the horizontal actuation shaft, a rotatable drive pinion gear driven by the horizontal drive rack gear, and a vertical driven rack gear driven by the rotatable drive pinon gear and operatively associated with a vertical valve stem. 8. The manifold assembly recited in claim 7 , wherein each horizontal drive rack gear is mounted to translate along a first horizontal axis, and wherein each rotatable drive pinion gear is mounted to rotate about a second horizontal axis that extends perpendicular to the first horizontal axis. 9. The manifold assembly recited in claim 1 , wherein each electro-mechanical valve actuator is a motorized rotary actuator, which includes a reduction gear assembly operatively associated with a vertical valve stem. 10. The manifold assembly recited in claim 1 , wherein each electro-mechanical valve actuator is a motorized rotary actuator, which includes an axial drive screw operatively associated with a vertical valve stem. 11. A manifold assembly for a surgical gas delivery system comprising: a) a three-dimensional manifold body having a horizontal top surface and a plurality of vertical side surfaces, and configured as a modular unit adapted to be enclosed within a housing of the surgical gas delivery system and including an inlet port for receiving a gas from an outlet side of a compressor and an outlet port for recirculating the gas to an inlet side of the compressor, wherein the inlet port and the outlet port are located on one of the side surfaces of the manifold body; b) a bypass valve located on the top surface of the manifold body and communicating with the inlet port and the outlet port of the manifold body through internal passageways defined within the manifold body, wherein the bypass valve includes a motorized linear valve actuator for dynamically controlling a flow of the gas through the bypass valve; c) an air ventilation valve located on the top surface of the manifold body and operatively associated with the inlet side of the compressor, wherein the air ventilation valve communicates with an air ventilation port provided on one of the side surfaces of the manifold body, and wherein the air ventilation valve includes a motorized linear valve actuator for dynamically controlling an ingress of air through the air ventilation port from an atmosphere; d) a smoke evacuation valve located on the top surface of the manifold body and operatively associated with the outlet side of the compressor, wherein the smoke evacuation valve communicates with a smoke evacuation port provided on one of the side surfaces of the manifold body, and wherein the smoke evacuation valve includes a motorized linear valve actuator for dynamically controlling an egress of the gas from the manifold assembly through the smoke evacuation port when the surgical gas delivery system is operating in a smoke evacuation mode; and e) a gas fill valve located on the top surface of the manifold body and operatively associated with the compressor, wherein the gas fill valve communicates with a gas fill port provided on one of the side surfaces of the manifold body, and wherein the gas fill valve includes a motorized linear valve actuator for dynamically controlling a receipt of the gas through the gas fill port from a source of surgical gas. 12. The manifold assembly recited in claim 11 , further comprising an over pressure