Emotor connection arrangement with phase bar cooling and compliant internal support in the junction box

What is claimed is: 1. An emotor connection arrangement for connecting power electronics of an electric or hybrid electric vehicle to an emotor, the emotor connection arrangement comprising: a junction box that is configured to extend from the power electronics to the emotor; phase bars that extend in the junction box and are adapted to electrically connect the power electronics to the emotor; a first access cover removably connected to the junction box and configured to provide access for connecting the phase bars to the emotor; a second access cover configured to provide access for connecting the phase bars to the power electronics; and the first access cover including a cooling fluid channel with a cooling fluid inlet configured to be connected to a cooling fluid source and a cooling fluid outlet configured to be connected to a cooling fluid return. 2. The emotor connection arrangement of claim 1 , wherein the first access cover includes a bottom surface that is configured to contact a potting material surrounding a connection part of the emotor that the phase bars are electrically connected to. 3. The emotor connection arrangement of claim 1 , wherein the cooling fluid channel has a linear path and the cooling fluid inlet and the cooling fluid outlet are located on opposite sides of the first access cover. 4. The emotor connection arrangement of claim 1 , wherein the cooling fluid channel has a curved path. 5. The emotor connection arrangement of claim 4 , wherein the curved path is arranged such that the cooling fluid inlet and the cooling fluid outlet are located on a same side of the first access cover. 6. The emotor connection arrangement of claim 1 , further comprising: the junction box including a first housing part and a second housing part that are configured to be connected together in an assembled position; a first insulating retainer configured to receive the phase bars; a second insulating retainer configured to be placed on the first insulating retainer such that the phase bars are held between the first and second insulating retainers; elastic tabs located on at least one of the first or second insulating retainers, the elastic tabs are configured to contact a respective inner surface of at least one of the first housing part or the second housing part, the elastic tabs being configured to generate a preload that presses the first and second insulating retainers toward one another and against the phase bars upon the first and second housing parts being connected together in the assembled position. 7. The emotor connection arrangement of claim 6 , wherein the elastic tabs are located on each of the first and second insulating retainers. 8. The emotor connection arrangement of claim 6 , wherein the first insulating retainer includes channels in which the phase bars are located that insulate the phase bars from one another. 9. The emotor connection arrangement of claim 8 , wherein the second insulating retainer includes clamping protrusions that are aligned with the channels in the first insulating retainer for clamping against the phase bars. 10. The emotor connection arrangement of claim 9 , wherein at least one of the first or second insulating retainer includes an alignment projection and the other of the first or second insulating retainer includes a corresponding alignment receptacle that receives the alignment projection. 11. The emotor connection arrangement of claim 6 , wherein the elastic tabs are configured to compensate for total tolerance accumulations of 4 mm and apply a load that presses the first and second insulating retainers toward one another and against the phase bars. 12. The emotor connection arrangement of claim 6 , wherein the first and second insulating retainers are formed of a glass filled polymer. 13. The emotor connection arrangement of claim 12 , wherein the glass is between 10 and 50 wt-% of the glass filled polymer, and the polymer is PPS. 14. An electric vehicle drive, comprising: an emotor including a stator and a rotor, a transmission including a torque converter, and the rotor being connectable to the torque convertor; power electronics configured to supply power to the emotor; an emotor connection arrangement configured to connect the power electronics to the emotor, the emotor connection arrangement including: a junction box that extends from the power electronics to the emotor; phase bars that extend in the junction box and are electrically connected to the power electronics and the emotor; a first access cover removably connected to the junction box and configured to provide access for connecting the phase bars to the emotor; a second access cover removably connected to the power electronics and configured to provide access for connecting the phase bars to the power electronics; and the first access cover including a cooling fluid channel with a cooling fluid inlet configured to be connected to a cooling fluid source and a cooling fluid outlet configured to be connected to a cooling fluid return. 15. The electric vehicle drive of claim 14 , wherein the first access cover includes a bottom surface that is configured to contact a potting material surrounding a connection part of the emotor that the phase bars are electrically connected to. 16. The electric vehicle drive of claim 14 , wherein the cooling fluid channel has a linear path and the cooling fluid inlet and the cooling fluid outlet are arranged on opposite sides of the first access cover. 17. The electric vehicle drive of claim 14 , wherein the cooling fluid channel has a curved path. 18. The electric vehicle drive of claim 17 , wherein the curved path is arranged such that the cooling fluid inlet and the cooling fluid outlet are located on a same side of the first access cover.