EP4255641A1 - Coating installation and associated operating method having a simulation of the amount of coating agent required - Google Patents

Abstract

The invention relates to a coating installation for coating components (14) with a coating agent, said coating installation comprising: a coating station (12) having a robot station, the robot station having a coating robot (15); a conveyor (13) for feeding the components (14) to be coated into the coating station (12); an information source (19) for providing a component identifier, the component identifier representing the component type of the component (14) and the coating agent type; a paint supply device (16) for providing the coating agent to be applied with a specific amount of coating agent; a pig launching station (1) at the paint supply device (16); a pig receiving station (3) at the robot station in the coating station (12); a pig line (2) that connects the pig launching station (1) to the pig receiving station (3); and a paint supply controller (11) for controlling the amount of coating agent. According to the invention, a simulation computer (18) is provided which simulates a coating of the component (14) and determines the amount of coating agent required as part of the simulation.

Description

DESCRIPTION

Coating plant and associated operating procedure with a simulation of the required amount of coating agent

territory of

The invention relates to a coating system for coating components with a coating agent, in particular for painting motor vehicle body components with a paint. Furthermore, the invention relates to a corresponding operating method for such a coating system.

Hey that

In modern paint shops for painting motor vehicle body components, rotary atomizers that are guided by painting robots are usually used as application devices. In this case, the painting robots are arranged in a painting booth, with the motor vehicle body components to be painted being conveyed through the painting booth by a conveyor and then being painted in the painting booth.

The paint to be applied is provided by a paint supply device and conveyed through a pig line to the respective robot station in the paint booth. For this purpose, the required amount of paint is first determined, which depends on the component type of the motor vehicle body to be painted and also on the paint type of the paint to be applied. The required quantity of paint is then filled into the pig line by the paint supply device at a pig source station and conveyed by a pig package along the pig line to a pig destination station at the respective robot station. There the paint is then removed from the pig package and used to paint the respective motor vehicle body. The paint remaining in the pig pack is then conveyed back to the pig source station along the pig line as part of a so-called reflow process. There, the so-called reflow paint can then be removed from the pig package again, which enables the paint to be reused. The problem with such painting systems is the determination of the required quantity of paint that is filled into the pig package and conveyed through the pig line to the robot station. It was already mentioned above that the amount of paint required depends on the type of component and the type of paint. However, due to the large number of component types used and the likewise large number of paint types used, it is hardly possible to have the required paint quantity ready in an assignment table for all combinations of component types and paint types. A great deal of maintenance is therefore required during ongoing painting operations in order to keep these allocation tables up to date, for example if a new type of paint or a new type of component has to be entered.

It can therefore happen in the paint shop that the amount of paint filled into the pig package does not exactly match the amount of paint actually required. Such fluctuations in the amount of paint filled into the pig pack compared to the amount of paint actually required also lead to corresponding fluctuations in the movement speed of the pig pack during the reflow process, since the movement resistance of the pig pack in the pig line depends on the amount of paint filled in. For this reason, in a reflow process, a specific residual quantity of paint that is as constant as possible should be returned to the pig pack in order to be able to maintain a defined pig speed as precisely as possible during the reflow movement. The fluctuations in the quantities of paint filled into the pig package in comparison to the quantity of paint actually required therefore lead to corresponding undesired fluctuations in the speed of the pig during the reflow process. However, such fluctuations in the speed of the pig during the reflow movement are undesirable for various reasons. In extreme cases, a pig speed that is too high can damage the pigs, while a pig speed that is too low leads to a loss of cycle time, i.e. the reflow process is too slow.

Furthermore, with regard to the technical background of the invention, reference should also be made to EP 1 837 726 A1, EP 1 270 083 A1, US 2006/0 086 407 A1, EP 1 380 350 A1, DE 101 20 11. A1 and DE 101 36 328 A1.

Description of the invention

The invention is therefore based on the object of solving the above-described problem of determining the required quantity of coating agent as precisely as possible as a function of the type of coating agent and the type of component. This object is achieved by a coating system according to the invention according to the main claim or by a corresponding operating method according to the additional claim.

The invention includes the general technical teaching of determining the amount of coating agent required for coating a component as a function of the respective type of coating agent and the respective type of component within the framework of a simulation, as will be explained in detail below.

The coating system according to the invention initially has at least one coating station (e.g. paint booth) with a robot station in accordance with the known coating system described above, in which a coating robot is arranged in order to coat the components with the coating agent.

In a preferred exemplary embodiment of the invention, the coating station is a painting booth which, apart from the inlet and/or outlet, has largely closed booth walls. With regard to the coating station, however, the invention is not limited to a largely closed paint booth, but can also be implemented, for example, with coating stations that are only functionally closed, but not spatially.

Furthermore, it should be mentioned that the invention is not limited to motor vehicle body components with regard to the components to be coated. Rather, the concept according to the invention is also suitable for coating other types of components.

In addition, it should also be mentioned that the invention is not limited to paint with regard to the coating agent to be applied. For example, the coating agent can also be an adhesive, an insulating material or a sealant, to name just a few examples.

In the preferred exemplary embodiment of the invention, the coating robot has a rotary atomizer as the application device. However, the invention is also not limited to rotary atomizers with regard to the application device used. For example, air atomizers or so-called print heads, which are known per se from the prior art, can also be used as application devices. In addition, the coating system according to the invention, in accordance with the known coating system described above, has a conveyor in order to convey the components to be coated into the coating station and to convey them out of the coating station again. Such conveyors are known per se from conventional painting systems for painting motor vehicle body components and therefore do not have to be described in more detail.

Furthermore, in accordance with the known coating system described above, the coating system according to the invention has an information source that provides a component identifier that is assigned to the component conveyed into the coating station, the component identifier in each case indicating the component type of the component conveyed into the coating station by the conveyor and the type of coating agent of the coating agent to be applied to the respective component.

In the preferred exemplary embodiment of the invention, this information source is a reading point which is arranged upstream of the coating station with respect to the conveyor, in particular at the inlet of the coating station, as is known per se from conventional painting systems for painting motor vehicle body components. This reading point can then read the component identifier attached to the component or to a component carrier (“skid”), with this reading process preferably being carried out wirelessly. For example, this reading process can be carried out using RFID (RFID: radio-frequency identification), using a barcode, using a light barrier matrix or using an inductive sensor solution, to name just a few examples.

Alternatively, however, there is also the possibility that the information source for providing the component identifier assigned to the component that has been conveyed in is a production controller. For example, the production control of a paint shop knows the component type of the motor vehicle body part that is fed in and also the paint type of the paint to be applied. In this case, no real reading point is required, since the production controller provides a virtual reading point.

In addition, the coating system according to the invention, in accordance with the known coating system described above, has a paint supply device in order to provide the coating agent to be applied with a certain quantity of coating agent that is required for coating the respective component according to the respective component type and the respective coating agent type. In practice, this paint supply device is usually arranged in a so-called paint mixing room, which is located at a distance from the paint booth.

Furthermore, the coating system according to the invention also has a pig source station at the paint supply device and a pig destination station at the respective robot station in the coating station, with the pig source station being connected to the pig destination station by a pig line in order to provide the necessary parts for coating the component to convey the amount of coating medium required at the robot station from the paint supply device through the pig line to the robot station.

The paint supply device is controlled by a paint supply controller, which specifies the required quantity of coating material, which is then filled into the pig line at the pig source station.

The invention is now distinguished from the known coating system described at the outset in that a simulation computer is provided which simulates a coating process of the respective component. In this simulation, the simulation computer takes into account the component identifier provided by the information source with the component type and the type of coating material. The simulation computer then calculates the quantity of coating material required for coating, taking into account the type of component and the type of coating material, and makes the value of the required quantity of coating material determined during the simulation available to the paint supply controller. The paint supply controller then controls the paint supply device in such a way that the pig line is filled with precisely the amount of coating material required beforehand. It should be mentioned here that, in addition to the required amount of coating material, a reflow amount can also be filled into the pig pack, with the reflow amount ensuring that the pig pack is not moved back dry during a reflow process.

In practice it can happen that the communication between the simulation computer and the paint supply control does not work, so that the required quantity of coating material determined by the simulation computer within the framework of the simulation cannot be transmitted to the paint supply control. In such a case, it makes sense for the paint supply controller to specify a standard quantity for the required quantity of coating material, so that the pig source station then fills the pig line with the standard quantity. Alternatively, there is the possibility that the paint supply control has a paint quantity memory in which the required standard quantity is stored for different types of components and different types of coating material. In the event of faulty reception of the required quantity of coating material from the simulation computer, the paint supply controller can then read out the standard quantity from the paint quantity memory in accordance with the component type and the type of coating material, so that the pig source station then fills the pig line with the standard quantity read out. In the event of disrupted communication between the simulation computer and the paint supply controller, the coating system according to the invention can therefore work in a similar way to the known coating material system described above, in which the allocation table with the assignment between component type and coating medium type on the one hand and the required quantity of coating medium on the other hand has to be maintained in a complex manner.

Furthermore, there is the possibility within the scope of the invention that the simulation computer stores a data set for each of the components for later evaluation, which contains the following data:

• component type of the component to be coated,

• Coating agent type of the coating agent to be applied, and

• the amount of coating agent required to coat the component, with the amount of coating agent required being determined by the simulation computer.

It has already been mentioned above that the required amount of coating agent is conveyed from the pig source station at the paint supply device to the pig destination station at the robot station. For this purpose, the required amount of coating agent is filled into a pig pack in the pig line, the pig pack comprising two pigs which enclose the required amount of coating agent between them. The pig source station then conveys the pig pack filled with the required amount of coating agent along the pig line to the pig destination station, where the required amount of coating agent can be removed from the pig pack.

After the end of the coating of a component, a certain amount of coating agent usually remains in the pig package, which is available for a so-called reflow process. After a component coating with a certain amount of the coating agent contained therein, the pig package is conveyed back from the pig target station to the pig source station. This backwards movement of the pig pack should not take place empty, ie without a filling of the pig pack with coating agent, since the friction of the pig pack in the pig line also depends on the amount of coating agent in the pig pack. In addition, the reverse movement of the pig pack during the reflow process should not take place when the pig pack is filled with too much coating material. As part of the reflow process, the pig pack should be filled with a precisely defined quantity of coating material, if possible, since the quantity of coating material also influences the movement speed of the pig pack when moving backwards to the pig source station. Excessive movement speed of the pig pack during the reflow process can damage the pigs. On the other hand, if the movement speed of the pig pack during the reflow process is too low, this costs cycle time, ie the entire process is slowed down.

The calculation according to the invention of the required quantity of coating agent now makes it possible for the quantity of coating agent remaining in the pig pack during the reflow process to be almost constant, which also leads to a correspondingly constant speed of movement of the pig pack during the reflow process. The return speed of the pig package when returning from the pig target station to the pig source station can therefore be largely independent of the type of coating material and the type of component, with the type-dependent deviations being limited to a maximum of 30%, 90%, 10% or even 5% . The same also applies to the amount of coating material returned as part of a reflow process, which can also be largely constant, with the type-dependent deviations being limited to a maximum of 30%, 90%, 10% or even 5%.

The movement of the pig package between the pig source station and the pig destination station can take place in a conventional manner by introducing compressed air into the pig line in each case in order to push the pig package to the pig source station or to the pig destination station.

It should also be mentioned that the robot station can have a station controller that controls the operation of the robot station. The above-mentioned simulation computer according to the invention can then be optionally integrated into the station controller or into the ink supply controller.

In addition to the coating system according to the invention described above, the invention also includes a corresponding operating method for such a coating system. The individual process steps of the operating process according to the invention are already evident from the above forthcoming description of the coating system according to the invention, so that a separate description of the individual process steps can be dispensed with.

Other advantageous developments of the invention are characterized in the dependent claims or are explained in more detail below together with the description of the preferred exemplary embodiment of the invention with reference to the figures.

Brief description of the drawings

FIG. 1 shows a schematic representation of part of a coating system according to the invention with a pig source station, a pig line and a pig destination station.

FIG. 2 shows a schematic representation of a painting system according to the invention for painting motor vehicle body components.

FIG. 3 shows a flowchart to explain the operating method according to the invention.

Detailed description of the drawings

The exemplary embodiment of a paint supply according to the invention shown in the drawings will now be described below, the paint supply in a paint shop for painting motor vehicle body components serving to supply a rotary atomizer (not shown) with the paint to be applied.

It should be mentioned here that the paint supply shown partially corresponds to the paint supply that is described in the earlier patent application DE 10 2021 131 136.5, so that reference is also made to this earlier patent application.

The paint supply has a pig source station 1, which is supplied with paint via a number of paint connections QFa-QFd.

The pig source station 1 is connected via a pig line 2 to a pig destination station 3, which forwards the paint to be applied to the rotary atomizer (not shown) via a connection ZF. In the pig line 2, a lubricant valve 4 is arranged, which will be described in detail. It should only be mentioned briefly at this point that the lubricant valve 4 is intended to introduce lubricant into the pig line 2 in order to reduce the friction in the pig line 2 .

Furthermore, there is a displaceable pig package in the pig line 2, which consists of two pigs, namely a pushout pig 5 and a reflow pig 6. A paint column 7 can be clamped in the pig package between the pushout pig 5 and the reflow pig 6 transported in a pushout process from the pig source station 1 to the pig destination station 3 and in a reflow process in the opposite direction from the pig destination station 3 to the pig source station 1.

The movement of the pig package from the pig source station 1 to the pig destination station 3 takes place in a pushout process in that a pushing medium (e.g. compressed air) is introduced into the pig line 2 at the pig source station 1 via a connection QMS, whereby the Push medium then transports the pig package with the pushout pig 5 and the reflow pig 6 along the pig line 2 to the pig target station 3.

In a reflow process, on the other hand, the pig package with the pushout pig 5 and the reflow pig 6 is transported along the pig line 2 in the opposite direction, i.e. from the pig destination station 3 to the pig source station 1. In the destination station 3, a pushing medium (e.g. compressed air) is fed into the pig line 2 via a ZMS connection, with the pushing medium then pressing on the reflow pig 6 and transporting the complete pig package with the paint column 7 clamped between them along the pig line 2 to the pig source station 1 . The paint column 7 returned to the pig source station 1 can then be returned to the paint connections QFa-QFd in order to enable reuse.

During the reflow process, the pig package with the pushout pig 5 and the reflow pig 6 and the paint column 7 clamped between them moves in the otherwise dry pig line 2, ie the pig line 2 is between the pushout pig 5 and the pig -Source station 1 empty. This leads to increased friction between the pushout pig 5 and the walls of the pig line 2, which has a negative effect on the service life of the pushout pig 5 and limits the maximum possible speed of movement of the pig pack during the reflow process, thus preventing damage to the pushout -Pig 5 or the reflow pig 6 is prevented. The invention therefore provides that, in a reflow process, a lubricant is fed into the pig line 2 between the pushout pig 5 and the pig source station 1, with the lubricant a lubricant column 8 then forms in the pig line 2 , which column is located in front of the pushout pig 5 in the reflow process with respect to the direction of movement of the pushout pig 5 . As a result, the friction of the pushout pig 5 during the reflow process in the otherwise empty pig line 2 is reduced, which allows for a greater speed of movement of the pig pack during the reflow process.

The introduction of the lubricant into the pig line 2 takes place through the lubricant valve 4 already mentioned above, which is arranged in the pig line 2 . However, when introducing the lubricant into the pig line 2, it must be prevented that the lubricant is fed into the paint column 7, which is clamped in the pig stack between the pushout pig 5 and the reflow pig 6. This would lead to contamination of the paint in the paint column 7, which would prevent the paint from being reused.

The paint supply according to the invention therefore has a sensor 9 which is arranged on the pig line 2 near the pig target station 3 and detects the fill level of the pig line 2 . During the reflow process, there is an air column 10 in the pig line 2 in the direction of movement in front of the pig pack with the clamped paint column 7, with the sensor 9 being able to detect whether the measuring point in the pig line 2 is the air column 10 or the paint column 7 located. The sensor 9 is queried by a control unit 11, which then controls the lubricant valve 4 accordingly. This means that lubricant is only fed into the pig line 2 via the lubricant valve 4 when the sensor 9 has detected that the air column 10 is located at the measuring point in the pig line 2 . If, on the other hand, the sensor 9 detects that the paint column 7 is in the pig line 2 at the measuring point, the control unit 11 blocks the feeding of the lubricant into the pig line 2.

What is important here is the position of the lubricant valve 4, which should be as close as possible to the pig destination station 3, so that the pushout pig 5 can, if possible, during its entire backward movement from the pig destination station 3 to the pig source station 1 within the scope of the reflow process is lubricated. The distance between the lubricant valve 4 and the pig destination station 3 along the pig line can therefore be less than 10 cm, for example.

Furthermore, the position of the sensor 9 along the pig line 2 is important. The sensor 9 should be located with its measuring point as close as possible to the lubricant feed point of the lubricant valve 4 . This is important so that the sensor 9 then detects the fill level of the pig line 2 at the lubricant feed point of the lubricant valve 4 . It should also be mentioned that the control unit 11 also controls numerous valves in the pig source station 1 and numerous valves in the pig destination station 3 in order to control the operation of the paint supply. At this point it should only be mentioned that the pig source station 1 has the following connections:

• QFa: paint connection of the pig source station for feeding paint a

• QFb: paint connection of the pig source station for feeding paint b

• QFc: paint connection of the pig source station for feeding paint c

• QFd: paint connection of the pig source station for feeding paint d

• QHD: Connection of the pig source station for high-pressure feed

• QMS: Connection of the pig source station for feeding push medium

• QND: Connection of the pig source station for low-pressure feed

• QRFad: Feedback in the pig source station for the flushing process

• QRFbc: return in the pig source station for the flushing process

• QV: Connection of the pig source station for supplying diluent

• RF: Feedback

• QZYe: Connection of the pig source station for retracting the cylinder

• QZYa: Connection of the pig source station for extending the cylinder

• QRFD: Connection of the pig source station for return throttle

• QMPI: Connection of the push-out initiator pig source station

• QMRI: Connection of the pig source station reflow initiator

It should also be mentioned that pig target station 3 also has the following connections:

• ZF: Connection of the pig target station for delivery of paint to the applicator

• ZRF: Connection of the pig target station for dispensing paint in return

• ZHD: Connection of the pig target station for high-pressure feed

• ZND: Connection of the pig target station for low-pressure feed

• ZMS: Connection of the pig target station for feeding the pig pusher medium

• ZRFD: Connection of the pig target station for return throttle

• ZMRI: pig target station pig reflow initiator

It should also be mentioned that the pig source station 1 is at an electrical earth potential during operation. The pig target station 3, on the other hand, can either be at earth potential or at high voltage. voltage potential to enable electrostatic charging of the coating material. When the pig target station 3 is charged to high-voltage potential, the pig line

2 completely emptied and cleaned in order to form the greatest possible electrical resistance, which creates a potential separation between the pig source station 1 on the one hand and the pig destination station

3 on the other hand allows.

FIG. 2 is now described below, which shows the integration of the pig system described above and shown in FIG. 1 in a paint shop.

The paint shop has a paint booth 12, with a conveyor 13 conveying the motor vehicle bodies 14 to be painted in the direction of the arrow through the paint booth 12, as indicated only schematically in the drawing by an arrow.

The pig target station 3 is arranged in the painting booth 12 and is used to supply paint to a painting robot 15.

In addition, the drawing shows a color mixing room 16 with the pig swelling station 1 arranged therein.

The drawing also shows that the control unit 11 already shown in Figure 1 controls the pig source station 1 so that the pig source station 1 fills the required quantity of paint into a pig package 17, which consists of the pushout pig 5 and the reflow pig 6 .

The required amount of paint is determined by a simulation computer 18 as part of a simulation of the painting process. Here, the simulation computer 18 takes into account the type of motor vehicle body 14 to be painted and also the paint type of the paint to be applied, since both variables (paint type and body type) influence the required paint quantity.

For this purpose, the paint shop has a reading point 19 which is arranged at the inlet of the paint booth 12 and reads out a component identifier on the incoming motor vehicle body 14 . This reading process can be carried out, for example, using an RFID transponder on the motor vehicle body 14 or by reading a barcode on the motor vehicle body 14. The component identifier read contains the component type of the motor vehicle body 14 and the paint type of the paint to be applied. This information is transmitted from the reading point 19 to the simulation computer 18, which then simulates the actual painting process and determine the required amount of paint. This value is then transferred to the control unit 11 for the color mixing room 16.

The control unit 11 then controls the pig source station 1 in such a way that the required quantity of paint is filled into the pig line 2 .

The control unit 11 then also controls the pig source station 1 in such a way that the pig package 17 with the quantity of paint filled in it is conveyed to the pig destination station 3 . For this purpose, compressed air is introduced into the pig line 2 at the pig source station 1 behind the pig pack 17 , the compressed air then pushing the pig pack 17 to the pig target station 3 .

After a component painting process, a certain amount of paint then remains in the pig pack 17. This remaining paint amount is then conveyed back to the pig source station 1 with the pig pack 17 as part of a reflow process. For this purpose, compressed air is introduced into the pig line 2 at the pig destination station 3 , the compressed air then guiding the pig package 17 back to the pig source station 1 . There, the quantity of paint remaining in the pig pack 17 can then be removed from the pig pack 17 and either disposed of or reused.

The flowchart according to FIG. 3, which explains the operating method according to the invention, is now described below.

In a first step S1, the paint type and the type of motor vehicle body 14 to be painted are first read at the reading point 19.

Then, in step S2, the painting process is simulated according to the type of paint and the type of body, with the required amount of paint being determined as part of the simulation.

The required quantity of paint is then transmitted to the control unit 11 of the paint mixing room 16 in a step S3.

The control unit 11 then controls the pig source station 1 in a step S4 in such a way that the required quantity of paint is filled into the pig package 17 in the pig line 2 . In the next step S5, the filled pig package 17 is then conveyed with the required amount of paint contained therein along the pig line 2 to the robot station with the pig target station 3.

The next step S6 then provides for the paint to be removed from the pig package 17 at the pig destination station 3 .

In the next step S7, the motor vehicle body 14 can then be painted with the removed paint at the robot station.

After completion of the painting process, a so-called reflow of the pig package 17 with the remaining paint from the pig target station 3 back to the pig source station 1 then takes place in a step S8.

In the pig source station 1, the paint remaining in the pig pack 17 can then be removed from the pig pack 17, which takes place in a step S9.

In the next step S10, the paint removed during the reflow process can then either be disposed of or reused.

The invention is not limited to the preferred embodiment described above. Rather, a large number of variants and modifications are possible, which also make use of the inventive idea and therefore fall within the scope of protection. In particular, the invention also claims protection for the subject matter and the features of the subclaims independently of the claims referred to in each case and in particular also without the features of the main claim. The invention thus comprises various aspects of the invention which are protected independently of one another.

Reference List

1 newt source station

2 pig line

3 pig destination station

4 Lubricant valve in the pig line

5 Pushout pig for pushing out the paint to be applied

6 Reflow pig for returning excess paint

7 Paint column between pushout pig and reflow pig

8 Lubricant column in front of the pushout pig

9 Sensor in the pig line

10 Air column in the pig line

11 control unit

12 paint booth

13 sponsors

14 Motor vehicle body

15 painting robots in the paint booth

16 color mixing room

17 pig package

18 simulation calculator

19 reading point

QFa paint connection of the pig source station for feeding paint a

QFb paint connection of pig source station for paint feed b

QFc paint connection of the pig source station for feeding paint c

QFd paint connection of pig source station for paint feed d

QHD Connection of the pig source station for feeding high pressure QMS Connection of the pig source station for feeding pushing medium QND Connection of the pig source station for feeding low pressure QRFad Return in the pig source station for flushing process QRFbc Return in the pig source station for flushing process QV Connection of the pig Source station for feeding thinner

RF feedback

QZYe Connection of the pig source station for retracting the cylinder QZYa Connection of the pig source station for extending the cylinder QRFD Connection of the pig source station for return throttle QMPI connection of the pig source station push-out initiator

QMRI connection of the pig source station reflow initiator

ZF connection of the pig target station for delivery of paint to the applicator

ZRF Connection of the pig target station for dispensing paint in return ZHD Connection of the pig target station for high-pressure feed

ZND Connection of pig target station for low-pressure feed

ZMS connection of the pig target station for feeding the pig pusher medium

ZRFD connection of the pig target station for return throttle

ZMRI pig target station pig reflow initiator

Claims

EXPECTATIONS

1. Coating system for coating components (14) with a coating agent, in particular for painting motor vehicle bodies (14) with a paint, with a) a coating station (12) with at least one robot station arranged in the coating station (12), the robot station having a coating robot (15) in order to coat the components (14) with the coating agent, b) a conveyor (13) for conveying the components (14) to be coated into the coating station (12), c) an information source (19) for provision a component identifier that is assigned to the component (14) conveyed into the coating station (12), the component identifier in each case identifying the component type of the component (14) conveyed into the coating station (12) by the conveyor (13) and the type of coating agent of the component on the respective Component (14) reproduces the coating agent to be applied, d) a paint supply device (16) for providing the coating agent to be applied with a certain amount of coating agent that is required for coating the respective component (14) according to the respective component type and the respective coating agent type, e) a pig source station (1) on the paint supply device (16), f) a pig target station (3) on the robot station in the coating station (12), g) a pig line (2) which the pig source station (1) with the pig target station (3) in order to convey the quantity of coating medium required for coating the component (14) at the robot station from the paint supply device (16) through the pig line (2) to the robot station, and h) a paint supply controller (11) for controlling the amount of coating agent that is filled into the pig line (2) by the paint supply device (16) at the pig source station (1) and conveyed through the pig line (2) to the pig destination station (3), characterized in that i) that a simulation computer (18) is provided, which simulates a coating of the respective component (14), j) that the simulation computer (18) receives from the information source (19) the component identifier with the component type and the type of coating agent for the respective component (14). , the is conveyed into the coating station (12) by the conveyor (13), k) the simulation computer (18) uses the component type and the coating agent type to calculate the required quantity of coating agent by simulating the coating, which is required at the robot station for coating the respective component (14 ) is required, and l) that the simulation computer (18) transmits the required quantity of coating agent to the paint supply controller (11), so that the paint supply controller (11) fills the required quantity of coating agent with the pig source station (1) into the pig line (2).

2. Coating system according to claim 1, characterized in that the paint supply controller (11) defines a standard quantity for the required quantity of coating medium in the event of faulty reception of the required quantity of coating medium from the simulation computer (18), so that the pig originating station (1) uses the pig line (2 ) filled with the standard quantity.

3. Coating system according to Claim 1, characterized in that a) the paint supply controller (11) has a paint quantity memory in which the standard quantity required in each case for different component types and different types of coating agent is stored, b) that the paint supply controller (11) if reception of the required amount of coating material reads the standard amount from the paint amount memory from the simulation computer (18), so that the pig source station (1) fills the pig line (2) with the standard amount.

4. Coating system according to one of the preceding claims, characterized in that the simulation computer (18) stores a data set for each of the components (14) for later evaluation, which contains the following data: a) the component type of the component (14) to be coated , b) the coating agent type of the coating agent to be applied, and c) the amount of coating agent required to coat the component (14) at the robot station, which was determined by the simulation computer (18).

5. Coating system according to one of the preceding claims, characterized in that a) the pig source station (1) fills the required quantity of coating agent into a pig pack (17) in the pig line (2), the pig pack (17) having two pigs (5, 6) which enclose the required amount of coating agent between them, b) that the pig swelling station (1) filled with the required amount of coating agent Pig package (17) conveys along the pig line (2) to the pig destination station (3), and c) that the pig destination station (3) removes the required quantity of coating agent from the pig package (17).

6. Coating system according to claim 5, characterized in that a) that the pig target station (3) after the end of a component coating the pig package (17) with the remaining coating agent at a certain return speed along the pig line (2) back to the pig source station (1) promotes, and b) that the pig source station (1) removes the coating agent from the returned pig package (17) for reuse or for disposal.

7. Coating installation according to claim 6, characterized in that a) the amount of returned coating agent is essentially constant, independently of the type of coating agent and also independently of the type of component, in particular with type-dependent deviations of at most 30%, 20%, 10% or 5%, and/or b) that the return speed of the pig package (17) during the return of the coating agent from the pig target station (3) to the pig source station (1) is essentially constant, independently of the type of coating agent and also independently of the type of component, in particular with type-dependent deviations of at most 30%, 20%, 10% or 5%.

8. Coating installation according to Claim 6 or 7, characterized in that a) the pig source station (1) conveys the pig package (17) to the pig destination station (3) in that the pig source station (1) sends compressed air into the pig line ( 2) initiates, with the compressed air pressing the pig package (17) to the pig destination station (3), and/or b) that the pig destination station (3) conveys the pig package (17) to the pig source station (1), in that the pig destination station (3) introduces compressed air into the pig line (2), the compressed air pressing the pig pack (17) to the pig source station (1).

9. Coating system according to one of the preceding claims, characterized in that a) the robot station has a station controller which controls the operation of the robot station, and b) that the simulation computer (18) is integrated into the station controller or into the paint supply controller (11).

10. Coating system according to one of the preceding claims, characterized in that a) that the coating station (12) is a coating booth (12) which is delimited by booth walls, and/or b) that the coating booth (12) b1) has only one inlet , in order to convey the components (14) through the inlet into the coating booth (12) and also to convey them out again through the inlet from the coating booth (12), or b2) has an inlet and an additional outlet, the components (14) to be coated through the inlet into the coating booth (12) and through the outlet out of the coating booth (12), and/or c) that the coating agent is a paint, an adhesive or an insulating material, and/or d) that the to be coated Components (14) are motor vehicle body components, and/or e) the coating robot (15) uses a rotary atomizer, an air atomizer or a print head as the application device for painting.

11. Coating installation according to one of the preceding claims, characterized in that a) the information source (19) for providing the component identifier assigned to the component (14) fed in is a reading point (19) which is located upstream of the coating station (13) with respect to the conveyor (13). 12), in particular at the inlet of the coating station (12), with the reading point (19) reading out the component identifier on the component (14) or on a component carrier, in particular wirelessly by means of a) RFID, a2) barcode, a3) a light barrier matrix or by means of a4) an inductive sensor solution, or b) that the information source (19) for providing the component identifier assigned to the component (14) fed in is a production controller.

12. Operating method for a coating system for coating components (14) with a coating agent, in particular for a coating system according to one of the preceding claims, with the following steps: a) determining a component type of the component (14) to be coated, b) determining a coating agent type of the coating agent to be applied to the component (14), c) determining the at a robot station in a coating station (12) for coating the amount of coating agent required for the component (14) as a function of the type of component and the type of coating agent, d) conveying the amount of coating agent required at the robot station for coating the component (14) through a pig line (2) from a pig source station (1) to a paint supply device ( 16) to a pig target station (3) at the robot station, e) removing the required amount of coating agent from the pig line (2) at the pig target station (3), and f) coating the component (14) with the material from the pig line ( 2) removed required amount of coating agent, characterized by the following step for determining the required amount of coating agent: g) simulation of a coating process using a simulation computer (18) according to the component type of the component (14) to be coated and the coating agent type of the coating agent to be applied to the component (14). .

13. Operating method according to claim 12, characterized by the following steps: a) conveying the component (14) to be coated into the coating station (12) by means of a conveyor (13), and b) reading out a component identifier of the component conveyed into the coating station (12). (14) by means of a reading point (19), the component identifier reflecting the component type of the component (14) conveyed into the coating station (12) by the conveyor (13) and the coating agent type of the coating agent to be applied.

14. Operating method according to Claim 12 or 13, characterized by the following steps for conveying the required quantity of coating from the pig source station (1) to the pig destination station (3): a) filling in the required quantity of coating agent at the pig source station (1) in a pig pack (17) with two pigs (5, 6), b) conveying the pig pack (17) with the quantity of coating agent contained therein from the pig source station (1) along the pig line (2) to the pig destination station (3), and c) removal of the required quantity of coating agent from the pig package (17) at the pig destination station (3).

15. Operating method according to claim 14, characterized in that a) that the pig destination station (3) after the end of a component coating, the pig package (17) with the remaining coating agent with a specific return speed along the pig line (2) back to the pig source station (1), and b) that the pig source station (1) removes the coating agent from the returned pig package (17) for reuse or for disposal.

16. Operating method according to claim 15, characterized in that a) that the pig source station (1) conveys the pig package (17) to the pig destination station (3) by the pig source station (1) blowing compressed air into the pig line (2) initiates, the compressed air pushing the pig package (17) to the pig destination station (3), and/or b) that the pig destination station (3) conveys the pig package (17) to the pig source station (1) by the Pig target station (3) introduces compressed air into the pig line (2), the compressed air pushing the pig pack (17) to the pig source station (1).

17. The operating method as claimed in claim 16, characterized in that a) the quantity of the returned coating agent is essentially constant independently of the type of coating agent to be applied and also independently of the type of component to be coated, in particular with type-dependent deviations of at most 30%, 20%, 10% or 5%, and/or b) that the return speed of the pig package (17) when returning the coating agent from the pig destination station (3) to the pig source station (1) independently of the type of coating agent of the coating agent to be applied and also independently of the component type of the component (14) to be coated is essentially constant, in particular with type-dependent deviations of at most 30%, 20%, 10% or 5%.