Quick-connect hydraulic coupling socket

The invention claimed is: 1. A hydraulic coupling socket comprising: an axially extending housing sleeve defining an axis; an axially centered and coaxial plunger in the housing sleeve having opposite end faces and an inner passage pressurizable by hydraulic fluid and extending from a hydraulic fluid supply port and extending toward the plunger; an axially movable pusher sleeve surrounding this plunger, the inner passage open axially in front of one of the end faces of the plunger into at least one opening on an outer surface of the plunger and through which the usher sleeve is pressurized from inside, the pusher sleeve and the plunger being sealed and movable position on one another axially inward and outward of the at least one opening; an axially movable retaining sleeve surrounding the pusher sleeve and having an outer surface in the housing, latch elements movable radially on the outer surface, bracing or freeing the outer surface, and having an annular end face that is at least substantially coplanar with end faces of the plunger and of the housing sleeve in a decoupled position; and means for pressurizing the pusher sleeve internally by a hydraulic fluid conducted through the socket in a manner at least substantially free of axial forces. 2. The socket according to claim 1 , wherein the pusher sleeve is biased by a compression spring toward the one of the end faces of the plunger. 3. The socket according to claim 1 , wherein, axially inward and outward of the at least one opening, the pusher sleeve and the plunger are secured adjacent one another, surfaces being provided on the pusher sleeve that are pressurized by the hydraulic fluid, of which at least one surface generates forces acting axially on the pusher sleeve toward the hydraulic fluid supply port, and of which at least one surface generates forces acting axially on the pusher sleeve toward the plunger, the forces vectorially canceling one another out or adding up to a remaining force that can be overcome manually during coupling. 4. The socket according to claim 1 , wherein at least one surface of the pusher sleeve pressurized by the hydraulic fluid generates a force directed axially to the hydraulic fluid supply port and is provided on an outer wall of the pusher sleeve that is pressurized by hydraulic fluid through a connection passage in the pusher sleeve wall from inside. 5. The socket according to claim 4 , wherein the connection passage connects an external annular space adjacent the pusher sleeve from outside to inside the pusher sleeve and/or the passage of the plunger, the external annular space being formed between the pusher sleeve and the housing sleeve or between the pusher sleeve and an insert in the housing sleeve. 6. The socket according to claim 5 , wherein the external annular space forms a reservoir accepting hydraulic fluid moved from inside the pusher sleeve during a movement in which an increase in volume of the external annular space caused during moving corresponds to a decrease in internal volume of the pusher sleeve. 7. The socket according to claim 1 , wherein, axially inward and outward of the at least one opening, the pusher sleeve and the plunger are secured adjacent each other. 8. The socket according to claim 7 , wherein, at one of the respective end faces, an outer surface of the plunger and an inner surface of the pusher sleeve are cylindrical with substantially the same diameter such that the at least one opening is radially opposite and immediately juxtaposed with the inner surface of the pusher sleeve. 9. A hydraulic coupling socket comprising: an axially extending housing sleeve, an axially extending pusher sleeve surrounding the housing sleeve, a plunger inside the housing sleeve, an axially movable pusher sleeve surrounding the plunger, an axially extending retaining sleeve surrounding the pusher sleeve and having a radially directed surface, a hydraulic coupling plug having latch elements in the housing sleeve, bracing or freeing the radially directed surface, and having an annular end face that is at least substantially coplanar with end faces of the plunger and the housing sleeve in a decoupled position, a limit stop, an inner piston in the housing sleeve that is fixed to the plunger and that can be moved axially with the housing sleeve such that, starting in the decoupled position, the plunger, the inner piston, and the pusher sleeve being movable jointly and axially into the housing sleeve up to an end position in which the hydraulic coupling plug can interlock with the hydraulic coupling socket via the latch elements, and, from the end position, first the plunger, the inner piston, and the pusher sleeve are moved jointly back up to a stop position in which the pusher sleeve is axially fixed to the limit stop, and, from the stop position, the plunger and the inner piston alone can be pushed further back, at least until a fluid passage is opened until the end faces of the plunger are coplanar with the end faces of the housing sleeve. 10. The socket according to claim 9 , wherein the inner piston is biased by hydraulic fluid in at least one control compartment that is delimited at least partially by an end face of the inner piston in which the at least one control compartment annularly surrounds the inner piston and is delimited by the inner piston and the housing sleeve. 11. The socket according to claim 9 , wherein the inner piston projects movably out of the housing sleeve on the side facing away from the hydraulic coupling plug, and has a supply port for the hydraulic fluid and connected through the inner piston with the fluid passage inside the pusher sleeve. 12. The socket according to claim 9 , wherein the inner piston is formed with a hydraulic fluid control line opening into the control compartment. 13. The socket according to claim 9 , wherein the inner piston is biased by the hydraulic fluid. 14. The socket according to claim 13 , wherein the inner piston is movable in an insert in the housing sleeve, which insert is surrounded by the hydraulic fluid through the hydraulic coupling socket, a control compartment delimited by the inner piston is in the insert, which control compartment has a separate fluid supply and drain. 15. The socket according to claim 14 , wherein the pusher sleeve has fluid passages running radially or diagonally to a longitudinal axis of the pusher sleeve and conducting the hydraulic fluid surrounding the insert into the pusher sleeve. 16. The socket according to claim 9 , wherein the inner piston separates two control compartments from one another, movement of the inner piston increasing volume of one of the two control compartments and decreasing volume of the other of the two control compartments. 17. The socket according to claim 16 , wherein the two control compartments are formed by an annular space coaxially surrounding the inner piston, and divided by an annular ridge on an outer surface of the inner piston, end faces on the inner piston axially flanking the ridge each delimiting a respective one of the control compartments. 18. The socket according to claim 16 , wherein the control compartment whose volume increases with movement of the inner piston during insertion of a hydraulic coupling plug into the hydraulic coupling socket is connected with an interior of the hydraulic coupling socket through which the hydraulic fluid is conducted through the socket to the plug. 19. The socket according to claim 16 , wherein the control compartment whose volume decreases with movement of the inner p