The invention relates to a control device for paint spraying systems and application systems which are used, in particular, for the quick-change application of paint in batch productions, with a piping system carrying fluids, such as paint, lacquer, coating particles, and solvents of different cleanliness classes, with individual separating elements, such as pigs, enabling a fluid separation inside the piping system.
Users of industrial paint spraying systems, such as those used, for example, in the assembly sequence in the automobile industry, are often confronted with the task of providing individual products (motor vehicles) or individual items of a batch production with a custom paint finish. In such cases, it is in the interest of an efficient and economical production to be able to quickly change the color, and this color change has to be performed with the spraying robots or hand spray guns that are in service without disrupting the flow of the assembly sequence. In order to satisfy this requirement, the production process is configured in such a way that the separation of the individual fluids is carried out inside the system's piping system that feeds the spraying robots and/or spray guns by conveying, on an alternating basis, charges of the different fluids, such as paint or cleaning solvents, through the piping system in succession and separated from each other. The amount of control engineering required for this purpose significantly increases the complexity and cost of existing systems.
With respect to the foregoing, the object of the present invention is to provide a control device that enables a quick change of the fluids to be applied to other components, such as the components of a vehicle body, at a low cost and with minimal technical complexity of the control system.
The invention achieves this object by means of a control device having the features specified in claim 1 in its entirety.
Accordingly, the control device according to the invention is characterized in that individual control blocks of the control device are composed of a plurality of actuatable switching valves, which enable, on the one hand, the input and/or output of pigs and/or, on the other hand, for this purpose, the simultaneous conveying of fluids in the piping system. The use of control blocks in which a plurality of switching valves, which perform a variety of control functions, are combined to form a control unit, reduces, compared to an operation of individual valve devices serving as control elements, both the complexity of the control system and also the design efforts, so that the result is a reduction in both the system costs and also the operating costs.
In especially advantageous exemplary embodiments, the piping system has an input control block at the beginning of a piggable pipeline that runs to at least one spraying station. This input control block has two switching valves, of which the first switching valve can be actuated as the controlling component of a pig launcher for the pigs and the second switching valve can be actuated to release and block the fluid inputs leading to the pipeline. The result of this arrangement is that all of the functions that are necessary for supplying the spraying station for the spraying operation and for changing the color can be executed by a single control block, in that one switching valve controls the fluid inputs for the fluids. In this case, one input can be provided for the paint, and at least one additional input can be provided for the cleaning solvents of different cleanliness classes, and the other switching valve for a necessary separation of the successive fluid flows controls the launching of the respective pigs.
The arrangement can be configured with a distinct advantage in such a way that the first switching valve of the input control block is arranged, based on the operational fluid flow, downstream of the second switching valve in the block and can be actuated for switching positions, in which either an input port for inserting a pig is released and a connection to the second switching valve is blocked, or this connection is released for the movement of the launched pig and/or the conveying of the respective fluid through the pipeline.
Preferably, the second switching valve, which is arranged upstream of the first switching valve in the input control block, can be actuated for switching positions, in which, on the one hand, a paint port is connected to the pipeline by means of a connection with the first switching valve; or, on the other hand, this connection is blocked; or, thirdly, the paint port is blocked, and the at least one fluid port for solvents of different cleanliness classes is connected to the pipeline by means of the connection with the first switching valve. Therefore, owing to the interaction of the first and second switching valves, all of the functions that are required to supply the spraying station and for changing the color are combined in one control block, including the launching of the necessary pigs.
The pipeline continues to run in an advantageous way from the respective spraying station to an end control block, which comprises two switching valves, of which one switching valve can be actuated for blocking and inputting an end of the pipeline that is connected to the block; and the second switching valve, which is situated downstream, is a controlling component of a pig receiver for pigs. The result of this arrangement is that once again the additional functions, which are necessary for retrieving the pertinent pigs, are also combined in one uniform control block.
The arrangement can be configured with a distinct advantage in such a way that a compressed air connection is provided at the fluid connection between the first and the second switching valve of the end control block. The result is that when the end of the pipeline is blocked, a pig, which has arrived at the end control block and is to be retrieved, can, through the admission of compressed air, be pushed out by way of the opened second switching valve.
In order to detect the position of the pig that is to be retrieved, a sensor, which signals the presence of a pertinent pig, can be provided at the fluid connection between the first and the second switching valve of the end control block. This approach can be implemented with a distinct advantage in such a way that the pigs have a permanent magnetic insert, so that a magnetic inductive sensor or a reed switch provides a notification signal.
In order to retrieve the pertinent pig, the arrangement can be configured in such a way that an output port for the pigs can be released or blocked with the second switching valve of the end control block.
Particularly advantageous exemplary embodiments provide a connecting line, which runs from the end control block to a distributor control block and which extends from a port at the end control block; and this port may be found at a fluid connection between the first and the second switching valve.
The distributor control block can comprise in an advantageous way five switching valves, which can be actuated for alternating connections from the connecting line to a first and/or a second paint reservoir or to a reservoir for slightly contaminated solvent or to a collector for highly contaminated solvent. The distributor control block can be used to recover the excess paint as well as the excess solvent, which was used in the course of the pig passage for precision cleaning, from the fluid flow, which arrives at said distributor control block from the pipeline, leaving the spraying station, by way of the end control block, for further use and to separate out the highly contaminated solvent that was used for preliminary cleaning.
The arrangement can be configured with a distinct advantage in such a way that the switching valves of at least one control block and preferably all of the control blocks are formed by ball valves comprising ball elements, which can be rotated by means of a respective controllable drive, which can be actuated as a function of the signal of an associated rotary position sensor and/or as a function of the signal of the pig sensor at the end control block and/or as a function of the signals from sensors that are distributed in the piping system and that detect the passing of pigs.
The invention is explained in detail below by means of one exemplary embodiment shown in the drawings. Referring to the drawings:
The invention is explained below by means of one exemplary embodiment, in which the control device is provided for the operation of a paint spraying system, as shown in schematic form in
The input control block 19, which is shown in detail in
In normal paint spraying operation, excess paint flows from the spraying station 3 over the connecting line 61 to the distributor control block 63 when the ball valve 45 is opened and the ball valve 47 of the end control block 21 is closed. In order to recover such excess paint, the distributor control block 63 establishes, starting from a paint output 65, the connection to the paint reservoir 43 (see
Then the launched pig 15 is moved by feeding in a preliminary cleaning solvent by way of the fluid port 37. In this case, a slightly contaminated solvent, used previously as the preliminary cleaning agent, is supplied from a preliminary cleaning solution reservoir 67 by way of a switching valve 69. The result is that the pig 15 is moved and forces the paint, located in the pipeline 9, through the end control block 21, of which the first ball valve 45 is opened and the second ball valve 47 is closed, as well as through the connecting line 61 to the distributor control block 63, of which the switching valves are switched in such a way that the paint is recovered and is returned from the paint output 65 to the paint reservoir 43. As soon as the pig sensor 51 at the end control block 21 determines the presence of the pig 15, the second ball valve 47 is opened, while the second ball valve 25 at the input control block 19 is switched over, in order to close the fluid input 37. Thereupon, the first ball valve 23 is actuated again in such a way that a second pig 15 is launched.
Upon completion, the second ball valve 25 is switched over again in such a way that by way of the fluid input 37 an unused, clean solvent can be supplied by way of the fluid input 37 for precision cleaning, with the clean solvent moving this pig 15, which displaces the highly contaminated solvent, which is loaded with residual paint and which may be found upstream of the pig, through the end control block 21 and the connecting line 61 to the distributor control block 63. At the same time, as soon as the second pig 15 begins to move, the second ball valve 47 at the end control block 21 is opened; and this ball valve releases the pig output 55. As a result, the highly contaminated solvent, which is moved by the second pig 15, forces the first pig 15, which may be found in the end control block 21, into the collecting tank 57 together with a portion of the highly contaminated solvent.
After this pig 15 has exited, the second ball valve 47 at the end control block 21 is closed again, so that the rest of the highly contaminated solvent is moved by the second pig through the connecting line 61 to the distributor control block 63, until the second pig 15 arrives in the end control block 21, a state that is signaled by the pig sensor 51. If this is the case, then the first ball valve 45 of the end control block 21 is closed, the second ball valve 47 is opened in order to release the pig output 55, and compressed air is admitted by way of a compressed air connection 74 (see
In order to change the color, the paint ports 39, 41 of the input control block 19 are connected to a corresponding paint reservoir for the changed color (in
In the course of the subsequent spraying process of the spraying station 3, the excess paint, which is delivered by way of the line section 13, flows in turn through the connecting line 61 to the distributor control block 63. Therefore, in the working cycle of spraying operation/color change, clean paint, clean solvent, slightly contaminated solvent, as well as a solvent which is highly contaminated by residual paint during the preliminary cleaning, flow on an alternating basis to the distributor control block 63. These fluids are divided in the distributor control block 63, as indicated symbolically in
Number | Date | Country | Kind |
---|---|---|---|
10 2012 005 080.1 | Mar 2012 | DE | national |