Rotary drive device and a robot arm of a robot equipped therewith

What is claimed is: 1. A rotary drive device comprising a fluid-actuated rotary drive, which has a drive housing and a drive unit rotatable relative thereto about a main axis of the rotary drive by a controlled fluid application to at least one pivot piston arranged in the drive housing, whereby a drive shaft of the drive unit connected to the pivot piston projects from the drive housing at an axial front side of the drive housing with a drive section enabling a force output, and with a control valve arrangement comprising at least one electrically actuatable control valve, which is fluidically connected via a control fluid channel system to two drive chambers of the rotary drive separated from one another by the pivot piston in the drive housing, and which is designed to control the fluid pressurization of the two drive chambers for rotation and rotative positioning of the drive unit relative to the drive housing, wherein a pressure detecting device is arranged on the fluid-actuated rotary drive, by which the fluid pressure prevailing in the drive chambers can be detected via pressure detecting channels opening into the two drive chambers and designed separately with respect to the control fluid channel system, for enabling a pressure-regulated operating mode of the fluid-operated rotary drive, and wherein the pressure detecting channels pass through a peripheral side wall of the drive housing radially outwardly bounding the drive chambers and open into the drive chambers on the inner circumferential surface of the peripheral side wall radially facing the main axis, and wherein a separate pressure detection channel opens out into each of the two drive chambers, and wherein a respective pressure sensor of the pressure detecting device is connected to each of the two separate pressure detection channels, and wherein a sensor holder is mounted radially outside on the drive housing, and wherein both of the pressure sensors of the pressure detecting device are arranged on the sensor holder. 2. The rotary drive device according to claim 1 , wherein the pressure detecting channels with internal channel entrances open into the drive chambers in such a way that these inner channel entrances lie outside of a pivoting range, which can be traversed by a wing section of the pivot piston during the pivoting movement of the pivot piston causing the rotation of the drive unit. 3. The rotary drive device according to claim 2 , wherein the pivot piston is arranged in a circular contoured housing interior of the drive housing and together with a partition wall element arranged in the housing interior subdivides the housing interior in a fluid-tight manner into the two drive chambers, wherein the partition wall element acts as a stop element by interacting with the wing section of the pivot piston to specify a maximum pivot angle of the pivot piston and wherein the inner channel entrances of the pressure detecting channels are located adjacent to the partition wall element in regions of the drive chambers which are outside of the pivoting range of the wing section defined by the maximum pivot angle of the pivot piston. 4. The rotary drive device according to claim 1 , wherein the control fluid channel system opens out into each drive chamber with an inner channel entrance of a working channel, wherein the inner channel entrances of the working channels are arranged respectively to one of two end walls of the drive housing of the rotary drive axially delimiting the drive chambers. 5. The rotary drive device according to claim 1 , wherein an electronic control unit connected with the control valve arrangement for the electric control thereof is arranged on the rotary drive, which is equipped with an electronic pressure regulation unit processing the fluid pressures detected in the drive chambers for rotational position control of the drive unit. 6. The rotary drive device according to claim 5 , wherein the electronic control unit is arranged on an the axial rear side of the drive housing opposite the axial front side. 7. The rotary drive device according to claim 5 , wherein the at least one control valve of the control valve arrangement is designed as an electrically controllable piezoelectric valve, wherein the electronic control unit has a high-voltage stage for generating a high-voltage drive voltage for the control valve arrangement. 8. The rotary drive device according to claim 5 , further comprising an encoder designed to detect the rotation angle of the drive unit, which is arranged on the axial rear side of the drive housing of the rotary drive, wherein the encoder has a movable encoder unit arranged on a detection section of the drive shaft protruding on the axial rear side of the drive housing and a fixed encoder unit attached to the drive housing and cooperating contactlessly with the movable encoder unit, wherein the fixed encoder unit is electrically connected to the electronic control unit. 9. The rotary drive device according to claim 1 , further comprising a pneumatic connection unit attached to the drive housing, which has, in an externally accessible manner, an aeration connection connectable or connected with an external pressure source and a deaeration connection connectable or connected to an external pressure sink, wherein the control valve arrangement is connected with both the aeration connection and with the deaeration connection. 10. The rotary drive device according to claim 1 , wherein the electronic control unit has an electromechanical interface device for connecting a bus system connected to a superordinate electronic control device. 11. The rotary drive device according to claim 10 , wherein the bus system is a serial bus system. 12. The rotary drive device according to claim 1 , further comprising a valve carrier device carrying the control valve arrangement and attached to the drive housing. 13. A rotary drive device comprising a fluid-actuated rotary drive, which has a drive housing and a drive unit rotatable relative thereto about a main axis of the rotary drive by a controlled fluid application to at least one pivot piston arranged in the drive housing, whereby a drive shaft of the drive unit connected to the pivot piston projects from the drive housing at an axial front side of the drive housing with a drive section enabling a force output, and with a control valve arrangement comprising at least one electrically actuatable control valve, which is fluidically connected via a control fluid channel system to two drive chambers of the rotary drive separated from one another by the pivot piston in the drive housing, and which is designed to control the fluid pressurization of the two drive chambers for rotation and rotative positioning of the drive unit relative to the drive housing, wherein a pressure detecting device is arranged on the fluid-actuated rotary drive, by which the fluid pressure prevailing in the drive chambers can be detected via pressure detecting channels opening into the two drive chambers and designed separately with respect to the control fluid channel system, for enabling a pressure-regulated operating mode of the fluid-operated rotary drive, and wherein the rotary drive further comprises a pneumatic connection unit attached to the drive housing, which has, in an externally accessible manner, an aeration connection connectable or connected with an external pressure source and a deaeration connection connectable or connected to an external pressure sink, wherein the control valve arrangement is connected with both the aeration connection and with the deaeration connection, and wherein the pneumatic connection unit is equipped with a further