Tube joints with consistent friction torque and no clearance gap

What is claimed is: 1. A bushing assembly comprising: a tube with an outer bearing surface; a metal part comprising an annular flange defining an opening in the metal part; a plastic bushing, with a bushing hub defining a tube opening with an inner annular bushing contact surface, the tube being received in the tube opening, and an axially extending metal part engagement surface; and a friction torque setting connection between the annular flange and the bushing hub, the friction torque setting connection defining a rotational and axial connection between the annular flange and the bushing hub and configured to vary a radial force applied between the annular flange and the bushing hub with a deformation of bushing plastic material to vary friction between the bushing contact surface and the tube outer bearing surface upon applying a torque to the plastic bushing causing rotation of the plastic bushing relative to the metal part and causing axial movement of the plastic bushing relative to the metal part and causing the deformation of plastic material of the bushing hub. 2. A bushing assembly according to claim 1 , wherein the torque applied to the plastic bushing sets the friction between the bushing contact surface and the tube outer bearing surface, based on a relationship between the friction between the bushing contact surface and the tube outer bearing surface and the torque applied to the plastic bushing. 3. A bushing assembly according to claim 2 , wherein: the annular flange has an inner flange surface defining the opening in the metal part; the friction torque setting connection comprises threading on the annular flange inner surface; bushing hub plastic material of the bushing hub has a change in bushing hub plastic material thickness over an axial extent of the bushing hub, whereby rotation of the plastic bushing relative to the metal part advances the engagement surface along a course of the threading to advance the inner flange surface axially relative to the surface of the bushing hub to deform the bushing hub plastic material in a contact region between the flange inner surface and the engagement surface. 4. A bushing assembly according to claim 3 , wherein: the annular flange inner flange surface is conical; and the engagement surface is conical and the bushing hub plastic material thickness increases from a plastic bushing axial front end to an axial rear end. 5. A bushing assembly according to claim 3 , wherein the engagement surface is conical and the bushing hub plastic material thickness increases from a plastic bushing axial front end to an axial rear end. 6. A bushing assembly according to claim 5 , wherein the plastic bushing further comprises a bushing flange extending radially outwardly from the bushing hub. 7. A bushing assembly according to claim 6 , wherein: the bushing flange comprises a circumferential engagement surface; the metal part comprises a circumferential engagement complementary surface; and the circumferential engagement surface engages the complementary surface to rotationally fix the plastic bushing relative to the metal part. 8. A bushing assembly according to claim 7 , wherein: the circumferential engagement surface comprises a plurality of grooves circumferentially spaced and arranged about a circumferential extent of the bushing flange; and the circumferential engagement complementary surface comprises at least one rib formed on a surface of the metal part surrounding the annular flange of the metal part. 9. A bushing assembly according to claim 8 , further comprising: an axial stop welded to the tube for stopping axial movement of the metal part and the plastic bushing, connected by the friction torque setting connection, relative to the tube in an axial direction; and a retaining ring axially fixed to the tube and in contact with the bushing flange, the retaining ring biasing the bushing flange toward the surface of the metal part to press one of the grooves to the at least one rib to rotationally fix the plastic bushing relative to the metal part. 10. A vehicle seat base assembly comprising: a vehicle seat base; and a bushing assembly comprising: a tube with an outer bearing surface; a metal part comprising an annular flange defining an opening in the metal part; a plastic bushing, with a bushing hub defining a tube opening with an inner annular bushing contact surface, the tube being received in the tube opening, and an axially extending metal part engagement surface; and a friction torque setting connection between the annular flange and the bushing hub, the friction torque setting connection defining a rotational and axial connection between the annular flange and the bushing hub and configured to vary a radial force applied between the annular flange and the bushing hub with a deformation of bushing plastic material to vary friction between the bushing contact surface and the tube outer bearing surface upon applying a torque to the plastic bushing causing rotation of the plastic bushing relative to the metal part and causing axial movement of the plastic bushing relative to the metal part and causing the deformation of plastic material of the bushing hub, wherein the metal part is a side bracket of the vehicle seat base. 11. A vehicle seat base assembly according to claim 10 , further comprising a further bushing assembly comprising: a further tube with a further tube outer bearing surface, wherein the side bracket comprises a further opening defined by a further annular flange; a further plastic bushing with a further bushing hub defining a further tube opening with a further inner annular bushing contact surface, the further tube being received in the further tube opening, and a further axially extending metal part engagement surface; and a further friction torque setting connection between the further annular flange and the further bushing hub, the further friction torque setting connection defining a rotational and axial connection between the further annular flange and the further bushing hub and configured to vary a radial force applied between the further annular flange and the further bushing hub with a deformation of bushing plastic material to vary friction between the further bushing contact surface and the further tube outer bearing surface upon applying a torque to the further plastic bushing causing rotation of the further plastic bushing relative to the metal part causing axial movement of the further plastic bushing relative to the metal part. 12. A vehicle seat base assembly according to claim 11 , wherein the torque applied to the further plastic bushing is essentially the same as the torque applied to the plastic bushing to set the friction between the further bushing contact surface and the further tube outer bearing surface essentially the same as the friction set between the bushing contact surface and the tube outer bearing surface. 13. A vehicle seat base assembly according to claim 12 , wherein: the annular flange has an inner flange surface defining the opening in the metal part; the friction torque setting connection comprises threading on the annular flange inner surface; bushing hub plastic material of the bushing hub has a change in bushing hub plastic material thickness over an axial extent of the bushing hub, whereby rotation of the plastic bushing relative to the metal part advances the engagement surface along a course of the threading to advance the inner flange surface axially relative to the surface of the bushing hub to deform the bushing hub plastic material in a contact region between the flange inner surface and the engagement surface.