Evaporator in a refrigerant circuit c

The invention claimed is: 1. An evaporator in a refrigerant circuit, comprising: an inlet chamber which is fluidly connected to an outlet chamber via evaporator tubes, and a separator integrated into the inlet chamber, the separator having an expansion member in which a refrigerant which is expanded as a two-phase liquid/vapour mixture and then divided into a vapour phase and into a liquid phase which is separate therefrom, wherein the vapour phase is conducted via a bypass line to the evaporator outlet chamber, wherein the liquid phase is conducted counter to the direction of gravity into the evaporator tubes, wherein the separator has a distributor tube which extends in the inlet chamber in the evaporator transverse direction and which has a reduced cross section in comparison with the inlet chamber, and wherein the two-phase liquid/vapour mixture flows via the distributor tube into the inlet chamber, characterized in that the distributor tube has at least one discharge opening, each of which is directed at a deflector wall, so that during operation, a refrigerant jet exiting from the discharge opening comes into contact with the deflector wall, resulting in a phase separation. 2. The evaporator according to claim 1 , wherein at least one evaporator tube is a flat tube with a plurality of micro-channels, through which the refrigerant is guided, wherein the micro-channels of the flat tube are divided into at least one vapour phase micro-channel and into at least one liquid phase micro-channel, and wherein the vapour phase micro-channel forms the bypass line, and exclusively the liquid phase flows into the liquid phase micro-channel. 3. The evaporator according to claim 2 , wherein the inlet chamber is delimited by a chamber bottom, side walls which are raised from the chamber bottom in the evaporator height direction, and a chamber top wall, wherein the evaporator tubes protrude through the chamber top wall into the inlet chamber in the evaporator height direction in such a way that at least one orifice opening of the micro-channels are spaced apart from the chamber bottom by a spacing, wherein the liquid phase collects in the inlet chamber with a filling level, wherein the liquid phase micro-channel is dipped with at least one of the at least one orifice opening into the liquid phase which is collected in the inlet chamber, wherein the vapour phase micro-channel is positioned with its orifice opening above a liquid phase level by a height offset, and wherein the orifice opening of the vapour phase micro-channel is spaced from the chamber bottom to a greater extent than the spacing of the orifice opening of the liquid phase micro-channel. 4. The evaporator according to claim 3 , wherein the orifice openings of the micro-channels are configured in a flat tube end side which is planar and faces the chamber bottom, and wherein the flat tube end side lies in an oblique plane which defines an oblique angle with a horizontal plane, so that different spacings between the orifice openings of the micro-channels and the chamber bottom are formed. 5. The evaporator according to claim 4 , wherein the spacings of the orifice openings of the micro-channels from the chamber bottom lie between a minimum spacing and a maximum spacing, and in that the minimum spacing is dimensioned in such a way that the filling level of the liquid phase which is collected in the inlet chamber is at least greater than the minimum spacing. 6. The evaporator according to claim 3 , wherein the inlet chamber is elongated in an evaporator transverse direction, wherein the evaporator has a plurality of evaporator tubes which are arranged behind one another and at a spacing in the evaporator transverse direction in an aligned manner in a parallel arrangement, wherein the parallel arrangement results in the formation of intermediate spaces between each evaporator tube, through which air can flow and which are arranged outside the inlet chamber, and wherein the plurality of evaporator tubes each have an identical separator geometry in the region of their respective orifice openings. 7. The evaporator according to claim 1 , wherein the at least one discharge opening is configured on the outer circumference of the distributor tube and is directed upwards in the evaporator height direction, and wherein the deflector wall is a chamber top wall. 8. The evaporator according to claim 3 , wherein the evaporator tubes protrude in each case with a tube projection from the chamber top wall into the inlet chamber, wherein at least one phase separation space is provided which is delimited by mutually facing flat sides of the tube projections, by the chamber top wall and by the chamber side walls, and wherein the refrigerant jet which exits from the distributor tube discharge opening is sprayed into the at least one phase separation space. 9. The evaporator according to claim 8 , wherein the distributor tube discharge opening is offset from the orifice openings of the evaporator tubes in the evaporator transverse direction by a transverse offset, with the result that the distributor tube discharge opening is directed directly onto the chamber top wall and the exiting refrigerant jet is guided past the orifice openings of the micro-channels. 10. The evaporator according to claim 7 , wherein the distributor tube protrudes beyond the liquid phase level at least with the discharge opening of the distributor tube, and wherein the distributor tube is positioned at least with its discharge opening in an inner corner region which is defined between the liquid phase level and an evaporator tube end side.