Hydrostatic piston machine unit

The invention claimed is: 1. A hydrostatic piston machine unit comprising: a first driving mechanism including first displacement pistons that are arranged in a first rotating cylinder part that defines a plurality of first cylinder spaces, each first cylinder space is configured to be alternately connected via a first respective connecting opening to a first low-pressure control port and a first high-pressure control port of a first stationary control part, on which two first changeover regions are arranged between the first low-pressure control port and the first high-pressure control port, the first displacement pistons configured to reverse direction of motion within the two first changeover regions at respective first dead center positions; a second driving mechanism including second displacement pistons that are arranged in a second rotating cylinder part that defines a plurality of second cylinder spaces, each second cylinder space configured to be alternately connected via a second respective connecting opening to a second low-pressure control port and a second high-pressure control port of a second stationary control part, on which two second changeover regions are arranged between the second low-pressure control port and the second high-pressure control port, the second displacement pistons configured to reverse direction of motion within the two second changeover regions, each of the first and second displacement pistons performing a reciprocating motion in operation so as to deliver fluid into a common pressure line or a common pressure connection via the respective first or second high-pressure control port; at least one cavity defining at least one precompression volume that is jointly assigned to both the first and second driving mechanisms; a first connecting line arranged in one of the two first changeover regions so as to connect the first cylinder spaces to a first cavity of the at least one cavity; and a second connecting line arranged in one of the two second changeover regions so as to connect the second cylinder spaces to the first cavity, wherein the first cavity is connected permanently in a restricted manner to the common pressure connection via a third connecting line. 2. The hydrostatic piston machine unit according to claim 1 , wherein: the at least one cavity includes the first cavity and a second cavity; one of the first and second cavities defines a first precompression volume of the at least one precompression volume provided for changeover from the first and second low-pressure control ports to the first and second high-pressure control ports; and the other of the first and second cavities defines a second precompression volume of the at least one precompression volume provided for changeover from the first and second high-pressure control ports to the first and second low-pressure control ports. 3. The hydrostatic piston machine unit according to claim 1 , wherein: each of the first respective connecting openings is configured to be connected in the one of the first changeover regions to the at least one cavity via a first outlet, which is arranged in the one of the first changeover regions, of the first connecting line, at the earliest when a connection to one of the first high-pressure control port and the first low-pressure control port is still restricted and before there is an overlap with the other of the first high-pressure control port and the first low-pressure control port; and each of the second respective connecting openings is configured to be connected in the one of the second changeover regions to the at least one cavity via a second outlet, which is arranged in the one of the second changeover regions, of the second connecting line, at the earliest when a connection to one of the second high-pressure control port and the second low-pressure control port is still restricted and before there is an overlap with the other of the second high-pressure control port and the second low-pressure control port. 4. The hydrostatic piston machine unit according to claim 3 , wherein: within a first angular range, one of the first respective connecting openings is open simultaneously to the first cavity and to a first respective control port of the first high-pressure and low-pressure control ports to which a changeover is being made, and to match a pressure in the first cavity to a pressure in the first respective control port, pressure fluid flows between the first respective control port and the first cavity via the one of the first respective connecting openings and via the first connecting line; and within a second angular range, one of the second respective connecting openings is open simultaneously to the first cavity and to a second respective control port of the first high-pressure and low-pressure control ports to which a changeover is being made, and to match a pressure in the first cavity to a pressure in the second respective control port, pressure fluid flows between the second respective control port and the first cavity via the one of the second respective connecting openings and via the second connecting line. 5. The hydrostatic piston machine unit according to claim 1 , wherein: the hydrostatic piston machine unit is an axial piston machine unit of swash plate design; and the first rotating cylinder part and the second rotating cylinder part are arranged in axial alignment with one another. 6. The hydrostatic piston machine unit according to claim 5 , wherein the first and second rotating cylinder parts are driven via a common shaft. 7. The hydrostatic piston machine unit according to claim 1 , wherein the first and second driving mechanisms each have the same number of respective first and second displacement pistons and are rotationally offset relative to one another by a half piston pitch in such a way that each of the first displacement pistons reverses direction of motion in a center of an angular interval between two of the second displacement pistons, and each of the second displacement pistons reverses direction of motion in a center of an angular interval between two of the first displacement pistons. 8. The hydrostatic piston machine unit according to claim 1 , wherein: the first and second driving mechanisms are rotationally offset relative to one another in such a way that each of the first displacement pistons reverses direction of motion in a center of an angular interval between two of the second displacement pistons, and each of the second displacement pistons reverses direction of motion in a center of an angular interval between two of the first displacement pistons; and alternately either only one of the first cylinder spaces or only one of the second cylinder spaces is connected directly to the first cavity. 9. The hydrostatic piston machine unit according to claim 1 , further comprising: a common housing accommodating the first and second driving mechanisms, the common housing defining the at least one cavity; a further pressure connection, which is common to the first and second driving mechanisms; and the pressure connection and the further pressure connection are formed on the common housing. 10. The hydrostatic piston machine unit according to claim 1 , wherein the hydrostatic piston machine unit is a hydrostatic axial piston machine unit. 11. The hydrostatic piston machine unit according to claim 1 , wherein the first cavity has a greater cross-sectional area than the first and second connecting lines. 12. A hydrostatic piston machine unit comprising: a first driving mechanism including first displacement pistons that are arranged in a first rotating cylinder part that defines a plura