Evaporator unit including distributor tube and method thereof

What is claimed is: 1. An inlet manifold for an evaporator of an air conditioning system, the inlet manifold comprising: a plurality of inlet slots configured for inserting refrigerant tubes of the evaporator for a refrigerant flow; a distributor tube located within the inlet manifold for aliguoting the refrigerant, a portion of the distributor tube flattened and bent toward an inlet port of the distributor tube along a longitudinal axis; and a mandrel inserted in the distributor tube for preventing the distributor tube from collapsing when the distributor tube is flattened and bent. 2. The inlet manifold of claim 1 , wherein the distributor tube includes the inlet port hydraulically connected to an expansion valve, a distal end located at an opposite end of the inlet port, and an open end bent toward the inlet port and extended to a middle area between the distal end and the inlet port along the longitudinal axis. 3. The inlet manifold of claim 1 , wherein the distributor tube is formed as a tubular section and a flattened section, and includes a transitional section from the tubular section to the flattened section. 4. The inlet manifold of claim 3 , wherein the tubular section of the distributor tube is formed from the inlet port to the transitional section and the flattened section of the distributor tube is formed from the transitional section to an open end. 5. The inlet manifold of claim 1 , wherein the portion of the distributor tube with the inserted mandrel is flattened and bent such that the inserted mandrel is permanently installed in a flattened section of the distributor tube. 6. The inlet manifold of claim 5 , wherein the mandrel further extends into a tubular section from the flattened section for preventing the inserted mandrel from blocking the refrigerant flow into the flattened section of the distributor tube. 7. The inlet manifold of claim 1 , wherein the distributor tube with the inserted mandrel is bent toward the inlet port of the distributor tube by 180 degrees along the longitudinal axis. 8. The inlet manifold of claim 1 , wherein the mandrel is formed as a hairpin shape including a pair of legs with a curved portion. 9. The inlet manifold of claim 8 , wherein the pair of legs of the mandrel are configured to keep a continuous open channel between the two legs inside a flattened section of the distributor tube for the refrigerant flow. 10. The inlet manifold of claim 1 , wherein a longitudinal length of the mandrel is longer than a longitudinal length of a flattened section of the distributor tube along the longitudinal axis. 11. The inlet manifold of claim 1 , wherein a diameter of the mandrel is equal to or less than an internal clearance of a channel formed by a flattened section of the distributor tube. 12. The inlet manifold of claim 1 , wherein the distributor tube inside the inlet manifold includes a plurality of orifices for equally aliquoting the refrigerant, and the orifices of the distributor tube are oriented away from open inlet ends of the refrigerant tubes. 13. A method of manufacturing an inlet manifold for an evaporator of an air conditioning system, comprising steps of: providing the inlet manifold with a plurality of inlet slots for inserting refrigerant tubes; providing a distributor tube for the inlet manifold; flattening a portion of the distributor tube; bending the flattened portion of the distributor tube toward an inlet port of the distributor tube along a longitudinal axis; and placing the distributor tube in the inlet manifold. 14. The method of claim 13 , wherein the method further comprises a step of inserting a mandrel into the distributor tube prior to flattening for preventing the distributor tube from collapsing when the distributor tube is flattened and bent. 15. The method of claim 14 , wherein the distributor tube with the inserted mandrel is bent toward the inlet port of the distributor tube by 180 degrees in the longitudinal axis. 16. The method of claim 14 , wherein the distributor tube is formed as a tubular section and a flattened section, and includes a transitional section from the tubular section to the flattened section. 17. The method of claim 16 , wherein the mandrel further extends into the tubular section from the flattened section for preventing the inserted mandrel from blocking a refrigerant flow into the flattened section of the distributor tube. 18. The method of claim 16 , wherein a longitudinal length of the mandrel is longer than a longitudinal length of the flattened section of the distributor tube along the longitudinal axis. 19. The method of claim 16 , wherein a diameter of the mandrel is equal to or less than an internal clearance of a channel formed by the flattened section of the distributor tube.