The invention concerns a valve unit according to the preamble of claim 1, especially for an atomizer under high voltage during operation for series coating of vehicle bodies, for example.
In known electrostatic rotary or air atomizers of this type (DE 4306800 A and Durr/Behr “EcoGun ESTA”), the paint line at the input to the atomization device is opened and closed with a paint needle valve, the so-called main needle valve, whose valve needle is pulled from the closed position against the force of a restoring spring into the open position by the piston of a pneumatic valve drive under control by the higher level program control system of the coating installation.
Feedback of at least one and preferably both switch positions of the main or paint needle valve is desirable for the higher level installation control. For example, in non-electrostatic air atomizers it was possible and common to generate the desired switch position signals with Hall sensors or inductive sensors mounted on the valve drive. These electric sensors, however, cannot be used in electrostatic atomizers that are under high voltage during operation. Although a switch position interrogation would also be important here, no practicable possibility has thus far been available for this.
Recording of the switch position of a valve needle for control of paint flow occurs, on the one hand, to monitor the switching function by feedback and, on the other hand, for valve control. By recording the time between the control signal of a valve needle and feedback of the switch position change in comparison with a stipulated reference value, deviations related to the operation (for example, by component wear) can be recognized and compensated in terms of process control. Because of this, especially in painting robots that operate with high painting speeds and frequent engagement/disengagement of valve needles, better constancy of the processes is possible.
There are also pneumatic sensors for interrogation of the switch position of valves, which, however, are too slow for the dynamic processes considered here.
The underlying task of the invention is therefore to provide a valve unit whose switch position even under high voltage can be interrogated as free of delay as possible.
This task is solved by the features of the patent claims.
With the invention, a potential-free and therefore switch position signaling also appropriate for electrostatic atomizers is made possible, for example, for main needle interrogation. The switch position of other valves situated in an electrostatic atomizer or in other components of a coating installation under high voltage can also be interrogated in the manner described here. The valve can also be a diaphragm valve.
The invention is further explained in the electrostatic rotary atomizer for direct charging of coating material shown in the drawing as an embodiment example. In the drawing,
The atomizer depicted in
A tappet or shaft element 10 that can be arranged coaxial with the valve needle 1, for example, within compression spring 8, is mounted on the piston 6 on its back side facing away from valve needle 1. The shaft element 10 according to the depiction expediently has on the periphery of its end part 11 facing away from piston 6 an optically reflecting surface element 12. The reflecting surface of element 12 can be flat and extend around the entire periphery, for example, of the square end part of the shaft (in cross section).
The end part 11 provided with the reflecting element 12 is shown in the drawing in the two switch positions of the main needle valve. They can be seen at 11, 12 in the (left) closed position, and in the valve open position at 11′, 12′(right). The needle lift H between these two switch positions can be about 5 mm.
The shaft 10 is moveable in a recess 14 of the valve housing coaxial to the needle axis, into which a radially running opening 15 leads, i.e., transverse to the needle axis through the housing.
A sensor device 16 includes a retaining or positioning element 17 for two optical waveguide units or sensors 20 and 21 that fit in opening 15, the optical faces of which are aligned with the inside wall of recess 14 at both sites at which the reflecting element 12, 12′ is situated in the two switch positions.
The reflecting element therefore lies right against the face of optical waveguide unit 20 when the main needle valve is closed and opposite the face of unit 21 when the valve is opened. The mutual spacing of the center axes of units 20, 21 corresponds to the valve needle lift H. As a result, the two switch positions can be reported by light signals that are formed when light is fed from the outside through the corresponding optical waveguide unit, reflected by the element 11, 11′ and fed back through the same optical waveguide unit (or possibly another optical waveguide) to an optoelectronic sensor (not shown), which can be situated outside of the high voltage region.
Optical waveguide sensor systems appropriate for the described purpose are known per se and need no further description.
Instead of the depicted arrangement of the reflecting surface element 12 on various or all peripheral parts on the end of the shaft element 10, which permits arbitrary rotational positions of the shaft with reference to the optical waveguide 20, 21, one reflecting surface only on the peripheral part facing the optical waveguide is sufficient. The switch position interrogation can also occur on other sites of the valve needle itself or a component moveable with it.
In some instances, a single optical waveguide unit can also be sufficient for interrogation of only one of the two switch positions.
Instead of the radial arrangement of the optical waveguide in the depicted practical example, it is also possible to arrange an optical waveguide axially along the shaft element, whose switch position is recognized by differently intense reflection.
Another possibility of modification is arrangement of at least one opto-electronic light barrier, for example, on the shaft element 10 for potential-free interrogation of one or both switch positions.
Especially when only one optical waveguide unit is arranged on the moveable shaft element 10 and the second optical waveguide 21 in
The binary signals triggered by the sensor in the two switch positions expediently have the same binary value. The binary signals are generated by the electronic sensor device, which is situated at a site removed from the valve outside of the high voltage region and is connected to the valve unit via the optical waveguide arrangement. When the shaft element 10 is displaced between its two positions, the sensor signal changes because of the region lying between the two signal generation elements initially into the opposite binary value before the first binary value is again generated on reaching the other valve position. By means of an electronic control device, it can be established whether, for example, after generation of a control signal for switching of the valve (and after disappearance of the first binary value), the first binary value is generated again as notification of the other valve position within a stipulated time. If this is not the case, a disturbance is present that is reported by an alarm signal.
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